Laureate Professor Behdad Moghtaderi
Laureate Professor
School of Engineering (Chemical Engineering)
- Email:behdad.moghtaderi@newcastle.edu.au
- Phone:(02) 40339062
The Energy Powerhouse
Driven by the desire to reduce greenhouse gases, Professor Behdad Moghtaderi is transforming the energy and mining sectors using his revolutionary GRANEX heat engine and greenhouse gas abatement technologies.
Attracting more than $48 million in research funding in the past 12 years and with more than 220 publications, the world-renowned chemical engineer has helped solve some of the biggest issues in improving energy efficiency and developing low emissions coal and renewable energy technologies.
"Reducing global greenhouse gas emissions has always been the driver of my research – the future of our planet depends on it," Professor Moghtaderi said.
"These innovations are not only important economically for industry, but to society's overall quality of life, health and environment," he said.
Professor Moghtaderi and his 30-strong research team, based at the University of Newcastle's world-class interdisciplinary research facility Newcastle Institute for Energy and Resources (NIER), are currently working on delivering safe, new methods of managing ventilation air methane (VAM) generated by underground coal mines.
The release of fugitive methane emissions is a by-product of underground coal mining and accounts for 64 per cent of all greenhouse gas emissions from the coal mining sector.
Announced in 2014, Professor Moghtaderi will lead two research projects that will address some of the major technical barriers to the full scale commercial deployment of VAM emissions abatement technologies, including the critical challenge of safe connection to the ventilation systems of underground mines.
The two projects received a total $30 million in funding from the Australian Government's Department of Industry and ACA Low Emissions Technologies Ltd.
Comparing his technologies to 'insurance' for climate change, Professor Moghtaderi said the VAM technology can potentially reduce fugitive methane emissions from underground coal mine operations by up to 90 per cent, reducing Australia's total national greenhouse gas inventory by about three percent and save industry millions.
"On an Australia-wide scale, removing VAM emissions from underground coal mining operations would be the equivalent to removing 2.8 million cars from our roads."
Once developed, the project outcomes will be equally applicable in other countries with underground coal mines.
"People take out home and car insurance to protect their assets and themselves from unknown events in the future. A similar rationale can be applied to energy technologies.
"We might not fully understand the impacts of climate changes, but are we comfortable with doing nothing and hoping that everything will be OK?"
This commitment has also seen Professor Moghtaderi and co-inventor Dr Elham Doroodchi and their teams to work with industry and develop GRANEX, an emission-free engine that turns heat from low-grade sources such as geothermal and industrial waste heat into electricity.
The research gained popular attention when GRANEX featured on the ABC TV's The New Inventors in 2011.
"I always enter my first lecture with a hot cup of coffee, which I place under a scaled model of a sterling engine connected to a propeller. The heat from my coffee powers the propeller blades of the model. It is a simple example of how waste heat can be used. I have been using that demonstration for ten years now and will never grow tired of seeing how excited it makes my students."
The technology delivers higher thermal efficiencies than conventional power plants, improving cycle efficiency and increasing the net electrical output from a given heat source by around 40 per cent.
A solar thermal combined power and heat plant using GRANEX is expected to be fully operational by March 2014 at the Wallsend public pool.
"We recently installed GRANEX technology to heat a local swimming pool. This is now a recreational resource for the community that can be used all year round, instead of just the warmer months."
"This is just one example of the commercial applications for GRANEX. It has significant potential international market value and could generate billions of dollars."
The revolutionary device is capable of using heat sources that might not otherwise be viably recycled, such as the flue gas from a coal-fired power station, exhaust from a diesel engine or heat from a geothermal source.
GRANEX was created after Granite Power Pty Ltd approached the University' commercial arm, Newcastle Innovation, looking for help to solve a problem they were having regarding developing commercially attractive geothermal energy technology.
Professor Moghtaderi said the ease with which industry could approach and work with global leaders had helped cement the University of Newcastle's reputation as being at the international forefront of research into clean and sustainable energy sources.
"The spirit of research here at the University of Newcastle is that we have a strong solutions-focused approach and want to see this research applied to the real world – we aim to be pragmatic and practical," said Professor Moghtaderi.
"With NIER, a world-class interdisciplinary research facility both here on campus, Newcastle truly is Australia's hub in energy research."
The Energy Powerhouse
Driven by the desire to reduce greenhouse gases, Professor Behdad Moghtaderi is transforming the energy and mining sectors using his revolutionary GRANEX heat engine and greenhouse gas abatement technologies.Attracting more than $48 million in research funding in the past 12…
Leading change
Our researchers are on a mission to reduce the world's greenhouse gas emissions
Professor Behdad Moghtaderi is on a mission to solve global energy challenges through world-leading research to develop low emissions coal technologies, renewable energy technologies and engineering solutions to improve energy efficiency in industry.
"I am driven by a desire to develop technologies that will help reduce greenhouse emissions. The future of our planet relies on it," says Professor Behdad Moghtaderi.
It is this passion that has equipped the chemical engineer to take a leading role in the University of Newcastle's Centre for Energy, a national leader in the research field of new-generation clean and renewable energy production. The Centre is a key component of the Newcastle Institute for Energy and Resources (NIER), a world-class interdisciplinary research facility on the University campus.
A consultant to government and industry, Professor Moghtaderi is a global thought leader, anticipating priorities for change and development in the energy sector. As a result, he has attracted more than $32 million in research funding in the past 12 years.
"We have recognised the research opportunities, and we are delivering results that are shaping government and industry agendas."
It is this influence and expertise that is generating sustainability outcomes on a global scale. His latest work involving Ventilation Air Methane, or VAM, may hold the key to unlocking one of the underground coal mining industries greatest environmental challenges. With the potential to reduce greenhouse gas emissions from underground coal mining operations by as much as 90 per cent, Professor Moghtaderi's VAM technology could lead to emissions reductions equivalent to the removal of 2.8 million cars from Australian roads.
Professor Moghtaderi gained popular attention when his GRANEX power platform featured on the ABC TV's The New Inventors in 2011. GRANEX, developed in conjunction with Granite Power Pty Ltd, is an emission-free engine that turns heat from low-grade sources into electricity.
It is revolutionary because it is capable of using heat sources that might not otherwise be viably recycled, such as the flue gas from a coal-fired power station, exhaust from a diesel engine or heat from a geothermal source.
Commercialised examples of his technologies are abundant and can be found throughout the world in power stations, the mining and minerals processing industry and community assets such as swimming pools.
Professor Moghtaderi compares his technologies to 'insurance' for climate change.
"People take out home and car insurance to protect their assets and themselves from unknown events in the future. A similar rationale can be applied to the technologies that fascinate me. We might not fully understand the impacts of climate change but are we comfortable with doing nothing and hoping that everything will be OK?"
Professor Moghtaderi firmly believes the University is at the international forefront of research into clean and sustainable energy sources.
"The University's engineering area has always been a leader and now, with our Centre for Energy and the Newcastle Institute for Energy and Resources on campus, Newcastle really is Australia's hub in energy research."
As a lecturer at the University of Newcastle, Professor Moghtaderi is taking steps to ensure this tradition continues by inspiring and cultivating the next generation of researchers.
"I always enter my first lecture with a hot coffee, which I place under a model of an engine and propeller. The heat from my coffee powers the propeller blades of the model. It's an example of the GRANEX technology. I have been using that demonstration for ten years now and will never grow tired of seeing how excited it makes my students."
With such enthusiasm for learning, it is easy to see how Professor Moghtaderi has received several teaching awards.
Looking to the future, Professor Moghtaderi hopes to continue his exploration of community applications of his technology.
"We recently installed GRANEX technology to heat a local swimming pool. This generated great outcomes for the community as it is now a recreational resource that can be used all year round, instead of just the warmer months."
Visit the Centre for Energy website.
Leading change
Energy expert Professor Behdad Moghtaderi is leading the way towards a cleaner future.
Career Summary
Biography
Professor Behdad Moghtaderi's research expertise is in the general field of energy and the environment. He has broad experience, knowledge and achievements in this field, particularly in application areas, such as renewable energy resources (e.g. biomass combustion / gasification, and geothermal power cycles), fire safety science, hydrogen powered micro-energy systems, and energy efficiency in buildings. Prof Moghtaderi has worked with both reacting and non-reacting flows, spanning gaseous and particle-laden flow from laboratory to pilot-scale experimental facilities and full-scale plants. His experience spans both the experimental, involving a wide range of laser-diagnostic and conventional techniques, to modelling using computational fluid dynamics (CFD). All are of direct relevance to the research program of the PRC-Energy. Prof Moghtaderi has worked closely with industry, government (Federal Government Geothermal Industry Round Table, Australian Greenhouse Office, etc) and international bodies (the International Energy Agency, IEA) on his research activities informing policy and practice. He served as the Honorary Secretary of The Australian and New Zealand Section of the Combustion Institute between 2007-2010. Within his area of expertise, Prof Moghtaderi has jointly published in excess of 220 articles and holds five patents. Since joining the University of Newcastle in 1999, Prof Moghtaderi has attracted in excess of $32M from the Australian Research Council (ARC) and industry to support his research activities. During this period he has secured 8 ARC-Discovery grants, 12 ARC-Linkage grants, 9 ARC-LIEF grants, 13 nationally competitive grants from none-ARC schemes, 23 industry grants and 21 University grants. Prof Moghtaderi greatly values the importance of research training and, as such, has been heavily involved with the supervision of postgraduate students. Since 1999, Prof Moghtaderi has had 14 PhD and two MSc completions by students under his supervision.
Research ExpertiseThe underlying theme of my research is Thermo-Fluid Engineering encompassing applications in the general field of energy and the environment. The focus of my research is development of technologies suitable for direct/indirect minimisation of greenhouse emissions. I have broad experience, knowledge and interests in this field, particularly in the following application areas which I have established since joining the University of Newcastle in 1999: * Renewable energy systems (e.g. biomass combustion, gasification and co-firing, as well as geothermal power); * Advanced clean coal technologies (e.g. oxy-fuel and chemical looping combustion); * Hydrogen powered micro-energy systems with an emphasis on microfluidics and micro-fabrication; * Energy efficiency (e.g. energy efficiency in buildings, energy efficient desalination), and fire physics. My research is underpinned by a wide range of novel and conventional experimental (e.g. laser-diagnostic, Micro-PIV) and modelling (e.g. computational fluid dynamics, CFD) techniques. I have extensive experience with both reacting and non-reacting flows, spanning gaseous and particle-laden systems from laboratory to pilot-scale facilities and full-scale plants. My research is cutting edge, well respected and internationally recognised. I have worked closely with industry, government, and international organisations on topics related to my research informing/influencing policy and practice. Through my research I have made significant contributions to the application areas listed above. The unique feature of these contributions is the fact that they provide detailed fundamental information about various technologies under conditions pertinent to the full-scale systems. As such, they have immediate applications in the engineering design of energy systems.
Teaching Expertise
I have taught many undergraduate courses since joining the University in 1997. My primary area of interest is courses related to thermo-fluid engineering. The courses I taught since 1997 include: CHEE111, CHEE1150, CHEE265, CHEE2820, CHEE2830, CHEE2690, CHEE357, CHEE372, CHEE3900, CHEE4210, CHEE4630, CHEE4950, and CHEE4970. I have also led and implemented several curriculum development initiatives, including: * Major revisions of chemical engineering and its associated double degree programs as part of the Faculty Engineering course rationalisation and introduction of the common first year program (revision in 2005, implementation 2006). * Played an instrumental role in the development of a new course-work Master program in Chemical Engineering. * Played an instrumental role in the Faculty of Engineering course rationalisation and introduction of the common first year and General Engineering courses such as GENG1000, GENG1002, GENG1803, GENG3830, (2004-2005). * Development of a Chemical Engineering program for future use in the PSB (Singapore) night program, (2005-2006). * Development of a Chemical/Mechanical Engineering program for UNISS scholars support by the Bradken Pty Ltd (2005). I have been the recepient of the following teaching awards: * The 2006 Carrick Awards for Australian University Teaching, Citations for Outstanding Contributions to Student Learning., citation was awarded for : the successful convergence of a student-centred and vertically integrated approach to design in engineering. The 2006 Vice Chancellors Citation for Outstanding Contributions to Student Learning (the University of Newcastle) for: the successful convergence of a student-centred and vertically integrated approach to design in Engineering. *The Institute of Engineers Australia (IEAust) Excellence in Engineering Education Award, 2002. *Several commendation letters from the PVC-Engineering for my teaching performance.
Administrative Expertise
I have proven experience and demonstrable record of planning, management and quality improvement of services at the university and professional levels. I have: * Simultaneously held four major administrative positions at the Discipline, Faculty and University levels (Chem Eng Program Convenor, Member of the Faculty Teaching and Learning Committee, Member of the Faculty Research Committee, Co-Director PRC-Energy) and have played an influential role in establishing new initiatives and reviewing/streamlining of existing policies/procedures. * Significantly contributed to professional activities through the membership of editorial boards and organising committees, refereeing scientific papers, assessing grant applications, and examining postgraduate theses. * Participated in a campaign to raise public awareness about global warming, renewable energy and clean coal technologies. * Provided expert advice to the International Energy Agency (IEA), the Australian Federal Government and the Australian Greenhouse Office on matters related to global warming, energy efficiency, renewable energy and clean coal technologies.
Qualifications
- PhD, University of Sydney
- Bachelor of Science (Mechanical Engineering), Shiraz University - Iran
- Master of Engineering Studies (Mechanical Eng), University of Sydney
Keywords
- Clean Coal Technologies (Chemical Looping Combustion, Oxy-fuel Combustion)
- Combustion
- Computational Fluid Dynamics (CFD)
- Energy Efficiency (Building Thermal Performance, Energy Efficeint Desalination)
- Energy Systems
- Engineering Design
- Engineering Mathematics
- Fluid Mechanics
- Heat Transfer
- Laser Diagnostics
- Mass Transfer
- Micro-Energy Systems (Microfluidics, Micro-reaction, Microfabrication)
- Process Simulation and Modelling
- Reaction Kinetics
- Renewable Energy Systems (Biomass Utilisation, Geothermal Power)
- Thermodynamics
Fields of Research
Code | Description | Percentage |
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400402 | Chemical and thermal processes in energy and combustion | 60 |
400803 | Electrical energy generation (incl. renewables, excl. photovoltaics) | 40 |
Professional Experience
UON Appointment
Title | Organisation / Department |
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Professor | University of Newcastle School of Engineering Australia |
Academic appointment
Dates | Title | Organisation / Department |
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1/3/2007 - | Member and Advisor | Industry Round Table on Geothermal Energy, Australian Federal Government Australia |
1/4/2005 - | Australian Representative | The International Energy Agency (IEA), Task 32, Biomass Combustion & Cofiring Australia |
1/1/2005 - | Associate Professor | University of Newcastle School of Engineering Australia |
1/1/2002 - 1/1/2005 | Senior Lecturer | University of Newcastle School of Engineering Australia |
1/1/1999 - 1/1/2002 | Lecturer | University of Newcastle School of Engineering Australia |
1/9/1998 - 1/1/1999 | Research Associate | The University of Adelaide School of Engineering Australia |
1/9/1998 - 1/1/1999 | Lecturer | The University of Adelaide School of Engineering Australia |
Membership
Dates | Title | Organisation / Department |
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Member of the Editorial Borad - Journal of BioResources | Journal of BioResources Australia |
|
Honorary Secretary - The Australia and New Zealand Section of the Combustion Institute | The Australia and New Zealand Section of the Combustion Institute Australia |
Awards
Distinction
Year | Award |
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2006 |
Fellow Institution of Engineers Australia (IEAust) |
Honours
Year | Award |
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2014 |
NSW Science & Engineering Award - Renewable energy innovation Office of the NSW Chief Scientist and Engineer |
2006 |
Citation Carrick Institute for Learning and Teaching in Higher Education |
Invitations
Participant
Year | Title / Rationale |
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2007 |
keynote paper: CFD Modelling of Coal/Biomass Co-Firing in PF Boilers Organisation: Indo-Australian Workshop on CFD Description: I delivered a keynote paper/presentation titled: "CFD Modelling of Coal/Biomass Co-Firing in PF Boilers" at the Indo-Australian Workshop on CFD, IIT Roorkee, India, 2007. |
2006 |
Keynote presentation (Biomass in Australia) Organisation: The Australians Academy of Technological Sciences and Engineering and The Indian Academy of Science Description: I was invited and delivered a keynote presentation on the topic of "Biomass in Australia" at the Joint meeting of the Indian Academy of Science and The Australians Academy of Technological Sciences and Engineering, Joint Sustainable Energy Workshop, CSIRO Energy, Newcastle, 5 Dec, 2006. |
2001 |
Keynote paper: Pyrolysis of Char Forming Solid Fuels: A Critical Review of the Mathematical Modelling Techniques Organisation: 5th Asia Oceania Symposium on Fire Science and Technology Description: I delivered a keynote paper/presentation titled: "Pyrolysis of Char Forming Solid Fuels: A Critical Review of the Mathematical Modelling Techniques", at The 5th Asia Oceania Symposium on Fire Science and Technology (AOSFST5), Australia, pp. 55-82, 2001. |
Publications
For publications that are currently unpublished or in-press, details are shown in italics.
Book (2 outputs)
Year | Citation | Altmetrics | Link | ||
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2011 |
Page AW, Moghtaderi B, Alterman D, Hands SA, A Study of the Thermal Performance of Australian Housing, Priority Research Centre for Energy, University of Newcastle, Newcastle, 193 (2011) [A2]
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2007 | Moghtaderi B, Ness J, Coal-Biomass Cofiring Handbook, Cooperative Research Centre for Coal in Sustainable Development, Kenmore, QLD, 284 (2007) [A3] |
Chapter (11 outputs)
Year | Citation | Altmetrics | Link | |||||
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2021 |
Albatayneh A, Alterman D, Page A, Moghtaderi B, 'Examining the Thermal Properties of Full-Scale Test Modules on the Overall Thermal Performance of Buildings', Advances in Science, Technology and Innovation, Springer Nature, Cham, Switzerland 169-177 (2021) [B1]
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2018 |
Momenzadeh L, Moghtaderi B, Liu X, Sloan S, Belova I, Murch G, 'The Thermal Conductivity of Magnesite, Dolomite and Calcite as Determined by Molecular Dynamics Simulation', Diffusion Foundations and Materials Applications, Scientific.Net, Baech, Switzerland 18-34 (2018) [B1]
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2018 |
Shiel J, Moghtaderi B, Aynsley R, Page A, Clarke J, 'Rapid Decarbonisation of Australian Housing in Warm Temperate Climatic Regions for 2050', Transition Towards 100% Renewable Energy: Selected Papers from the World Renewable Energy Congress WREC 2017, Springer, Cham, Switzerland 509-521 (2018) [B1]
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2014 |
Shiel J, Moghtaderi B, Aynsley R, Page A, 'Reducing the energy consumption of existing residential buildings, for climate change and scarce resource scenarios in 2050', Weather Matters for Energy, Springer, New York 467-493 (2014) [B1]
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2008 | Moghtaderi B, 'Co-combustion', The Handbook of Biomass Combustion and Co-Firing, Earthscan, Oxford, United Kingdom 203-248 (2008) [B1] | Nova | ||||||
2007 | Moghtaderi B, Ness J, 'Technical issues associated with co-combustion and ash deposition', Coal-Biomass Cofiring Handbook, Cooperative Research Centre for Coal in Sustainable Development, Brisbane, Queensland 155-192 (2007) [B1] | |||||||
2007 | Moghtaderi B, Ness J, 'Fuel handling and processing issues associated with the cofiring of biomass and coal', Coal-Biomass Cofiring Handbook, Cooperative Research Centre for Coal in Sustainable Development, Brisbane, Queensland 109-154 (2007) [B1] | |||||||
2007 | Ness J, Moghtaderi B, 'Biomass and bioenergy', Coal-Biomass Cofiring Handbook, Cooperative Research Centre for Coal in Sustainable Development, Brisbane, Queensland 1-36 (2007) [B1] | |||||||
2007 | Ness J, Moghtaderi B, 'Case studies', Coal-Biomass Cofiring Handbook, Cooperative Research Centre for Coal in Sustainable Development, Brisbane, Queensland 245-282 (2007) [B1] | |||||||
2002 | Moghtaderi B, Novozhilov V, Fletcher DF, Kent JH, 'The Effect of Char Oxidation on the Flaming Combustion Characteristics of Wood Materials', The Behaviour of Glass and Other Materials Exposed to Fire, Baywood Publishing Company, Inc., Amityville, New York 165-178 (2002) [B1] | |||||||
Show 8 more chapters |
Journal article (256 outputs)
Year | Citation | Altmetrics | Link | ||||||||
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2024 |
Lovis L, Maddocks A, Tremain P, Moghtaderi B, 'Optimising desiccants for multicyclic atmospheric water generation: Review and comparison', Sustainable Materials and Technologies, 39 (2024) [C1] Atmospheric water generators produce liquid water from humidity in the air. Hence, this technology provides a pathway to alleviate water scarcity. In contrast to conventional day-... [more] Atmospheric water generators produce liquid water from humidity in the air. Hence, this technology provides a pathway to alleviate water scarcity. In contrast to conventional day-night monocyclic systems, multicyclic atmospheric water generators conduct multiple sorption and desorption cycles per day. The specific water production for multicyclic desiccant based atmospheric water generators primarily depends on the water sorption and desorption rates of the desiccant, as opposed to the uptake capacity. The mechanisms governing the equilibrium uptake capacity of desiccants and the interparticle diffusion rate of water vapour are well known, however, the mechanisms governing the intraparticle diffusion and sorption rate of water vapour within desiccants are not well summarised. In this review, methods for the enhancement of the intraparticle water vapour diffusion and macroscopic sorption rate are identified, including the effects of pore microstructure, surface hydrophilicity, and composites. Additionally, desiccants with the highest potential specific water production and lowest potential specific energy consumption are identified. To date, the polyamide 6-LiCl nanofibrous membrane demonstrates the highest ideal specific water production of 230 L.kg-1.day-1. The ideal specific energy consumption is similar between the investigated desiccants and primarily depends on the latent heat of sorption. Furthermore, the suitability of various empirical kinetic models for the investigated desiccants is discussed. The variable order model provides a better fit to sorption and desorption kinetic data than the commonly used linear driving force model.
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2023 |
Peng Z, Zanganeh J, Moghtaderi B, 'Influence of Gradually Inflated Obstructions on Flame Propagation in a Tube Closed at One End', Fire, 6 154-154 [C1]
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2023 |
Jalalabadi T, Wu J, Moghtaderi B, Sharma N, Allen J, 'A new approach to turbostratic carbon production via thermal salt-assisted treatment of graphite', Fuel, 348 (2023) [C1] Here graphite was found to undergo carbon/carbonate gasification at 800 °C, resulting in exfoliation of graphite to form turbostratic carbon. The lattice distance of graphene shee... [more] Here graphite was found to undergo carbon/carbonate gasification at 800 °C, resulting in exfoliation of graphite to form turbostratic carbon. The lattice distance of graphene sheets in graphite are shown to undergo marked changes following treatment with molten ternary eutectic carbonate (Li2CO3: 43.5%, Na2CO3: 31.5%, K2CO3: 25%) during slow temperature ramping rates (5 °C/min) under N2 at temperatures above 750 °C. Initial findings suggest that approximately 50 wt% of graphite experiences interlayer expansion. The conventional d spacing of 0.34 nm is modified to a range of intervals between 0.41 nm and 1.22 nm. As a consequence of high operational temperature (800 °C), cations (Li+, Na+ and K+) as well as potentially the anion (CO32¿) intercalate between graphitic layers and overcome Van der Waal force between layers. Employing a pressurized N2 environment of 5 bar and 10 bar successfully controls carbonate vaporization and decomposition, as well as inducing ordered layer manipulation to exfoliate more graphite planes from the edges towards deeper levels of the particles. Exploring parameters of both carbonate loading and treatment time in addition to pressure demonstrate that this work opens up a rich selection of parameters that can be used to produce carbons with tuned properties from graphite.
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2023 |
Gai S, Peng Z, Moghtaderi B, Doroodchi E, 'Escape of an air bubble from a droplet under power ultrasound', Experimental Thermal and Fluid Science, 148 110986-110986 (2023) [C1]
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2023 |
Shirzaei M, Zanganeh J, Moghtaderi B, 'Obstacle Impacts on Methane-Air Flame Propagation Properties in Straight Pipes', Fire, 6 (2023) [C1] Accidental flame initiation to propagation in pipes carrying flammable gases is a significant safety concern that can potentially result in loss of life and substantial damage to ... [more] Accidental flame initiation to propagation in pipes carrying flammable gases is a significant safety concern that can potentially result in loss of life and substantial damage to property. The understanding of flame propagation characteristics caused by methane¿air mixtures within various extractive and associated process industries such as coal mining is critical in developing effective and safe fire prevention and mitigation countermeasures. The aim of this study is to investigate and visualise the fire and explosion properties of a methane¿air mixture in a straight pipe with and without obstacles. The experimental setup included modular starting pipes, an array of sensors (flame, temperature, and pressure), a gas injection system, a gas analyser, data acquisition and a control system. The resulting observations indicated that the presence of obstacles within a straight pipe eventuated an increase in flame propagation speed and deflagration overpressure as well as a reduction in the elapsed time of flame propagation. The maximum flame propagation speed in the presence of an orifice with a 70% blockage ratio at multiple spots was increased around 1.7 times when compared to the pipe without obstacles for 10% methane concentration. The findings of this study will augment the body of scientific knowledge and assist extractive and associated process industries, including stakeholders in coal mining to develop better strategies for preventing or reducing the incidence of methane¿air flame propagation caused by accidental fires.
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2023 |
Zanganeh J, Gwynne K, Peng Z, Moghtaderi B, 'Investigation of Hydrokinetic Tidal Energy Harvesting Using a Mangrove-Inspired Device', Sustainability, 15 15886-15886 [C1]
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2023 |
Lovis L, Tremain P, Maddocks A, Moghtaderi B, 'Modelling of atmospheric water generation using desiccant coated heat exchangers: A parametric study', Energy Conversion and Management, 279 (2023) [C1] Water scarcity is a significant issue in developing countries and remote locations, however, atmospheric water vapour is a widely available and yet underutilised water reservoir. ... [more] Water scarcity is a significant issue in developing countries and remote locations, however, atmospheric water vapour is a widely available and yet underutilised water reservoir. Desiccant coated heat exchangers are a potential sorption reactor for multicyclic atmospheric water generation due to the enhanced heat and mass transfer to the desiccant. This study utilised a transient one-dimensional mathematical model for a plate-fin desiccant coated heat exchanger and adapted the model for atmospheric water generation. From this, a heat and mass transfer analysis and parametric study were conducted to determine the effect of the operational and geometric parameters on the specific water production and specific energy consumption. The heat and mass transfer analysis found that the coating at the inlet and outlet regions of the channels were underutilised. The parametric study found that the adsorption and desorption cycle times should be optimised independently, the primary air velocity should be high during adsorption and low during desorption, and secondary channel cooling during adsorption did not significantly improve performance. The highest specific water production and the lowest specific energy consumption recorded in this study were 5.8 L kg-1 day-1 and 7.7 MJ L-1 respectively. The recorded specific water production values were higher than most desiccant based atmospheric water generators in the literature. However, the performance was significantly reduced at higher ambient temperatures.
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2023 |
Rahimpour HR, Zanganeh J, Moghtaderi B, 'Abatement of Greenhouse Gas Emissions from Ventilation Air Methane (VAM) Using Ionic Liquids: A Review of Experimental Methods and Modelling Approaches', Processes, 11 (2023) [C1] Ventilation Air Methane (VAM) refers to the release of fugitive methane (CH4) emissions into the atmosphere during underground coal mining operations. Growing concerns regarding t... [more] Ventilation Air Methane (VAM) refers to the release of fugitive methane (CH4) emissions into the atmosphere during underground coal mining operations. Growing concerns regarding the greenhouse effects of CH4 have led to a worldwide effort in developing efficient and cost-effective methods of capturing CH4. Among these, absorption-based processes, particularly those using Ionic Liquids (ILs) are appealing due to their advantages over conventional methods. In this study, the solubility of CH4 in various ILs, expressed by Henry¿s law constant, is first reviewed by examining a wide range of experimental techniques. This is followed by a review of thermodynamic modelling tools such as the extended Henry¿s law model, extended Pitzer¿s model, Peng¿Robinson (PR) equation of state, and Krichevsky-Kasarnovsky (KK) equation of state as well as computational (Artificial Neural Network) modelling approaches. The comprehensive analysis presented in this paper aims to provide a deeper understanding of the factors that significantly influence the process of interest. Furthermore, the study provides a critical examination of recent advancements and innovations in CH4 capture by ILs. ILs, in general, have a higher selectivity for methane compared to conventional solvents. This means that ILs can remove methane more effectively from VAM, resulting in a higher purity of the recovered methane. Overall, ILs offer several advantages over conventional solvents for the after treatment of VAM. They are more selective, less volatile, have a wider temperature range, are chemically stable, and can be made from renewable materials. As a result of their many advantages, ILs are becoming increasingly popular for the after treatment of VAM. They offer a more sustainable, efficient, and safe alternative to conventional solvents, and they are likely to continue gaining market share in the coming years.
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2022 |
Peng Z, Wang G, Moghtaderi B, Doroodchi E, 'A review of microreactors based on slurry Taylor (segmented) flow', Chemical Engineering Science, 247 (2022) [C1]
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2022 |
Islam F, Tahmasebi A, Moghtaderi B, Yu J, 'Structural Investigation of the Synthesized Few-Layer Graphene from Coal under Microwave', NANOMATERIALS, 12 (2022) [C1]
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2022 |
Gai S, Peng Z, Moghtaderi B, Yu J, Doroodchi E, 'LBM study of ice nucleation induced by the collapse of cavitation bubbles', COMPUTERS & FLUIDS, 246 (2022) [C1]
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2022 |
Gai S, Peng Z, Moghtaderi B, Yu J, Doroodchi E, 'Freezing of micro-droplets driven by power ultrasound', CHEMICAL ENGINEERING SCIENCE, 251 (2022) [C1]
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2021 |
Jalalabadi T, Moghtaderi B, Allen J, 'The interplay between ternary molten carbonate and biomaterials during pressurized slow pyrolysis', REACTION CHEMISTRY & ENGINEERING, 7 674-690 (2021) [C1]
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2021 |
Gai S, Peng Z, Moghtaderi B, Yu J, Doroodchi E, 'Ice nucleation of water droplet containing solid particles under weak ultrasonic vibration', Ultrasonics Sonochemistry, 70 (2021) [C1]
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2021 |
Peng Z, Zanganeh J, Moghtaderi B, 'CFD Modeling of Flame Jump across Air Gap between Evase and Capture Duct for Ventilation Air Methane Abatement', PROCESSES, 9 (2021) [C1]
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2021 |
Alghamdi YA, Peng Z, Almutairi Z, Alibrahim H, Al-Alweet FM, Moghtaderi B, Doroodchi E, 'Assessment of correlations for minimum fluidization velocity of binary mixtures of particles in gas fluidized beds', Powder Technology, 394 1231-1239 (2021) [C1] Gas fluidized beds with bi-dispersed particles of different sizes, densities, and shapes are encountered in many industrial processes spanning the manufacture of energy, material ... [more] Gas fluidized beds with bi-dispersed particles of different sizes, densities, and shapes are encountered in many industrial processes spanning the manufacture of energy, material and resources to greenhouse emissions mitigation and renewable resources utilization. The design and operation of such systems heavily rely on the prediction of minimum fluidization velocity of the mixture (Umf(mixture)) to avoid particle segregation and maximize mixing. Many correlations exist for predicting Umf(mixture); however, they exhibit limitations in accuracy and/or applicability. The limitations of these correlations are often expressed in terms of particles properties (e.g. effective size and density), flow conditions, and solids composition. This study has critically assessed highly cited correlations, delivered a comparative analysis of their applicability and predictability against a large pool of experimental data, and deepened the understanding of parameters that affect the prediction of Umf(mixture) using different correlations.
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2021 |
Liu Z, Alterman D, Page A, Moghtaderi B, Chen D, 'An experimental study on the thermal effects of slab-edge-insulation for slab-on-grade housing in a moderate Australian climate', ENERGY AND BUILDINGS, 235 (2021) [C1]
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2021 |
Gurieff N, Moghtaderi B, Daiyan R, Amal R, 'Gas transition: Renewable hydrogen s future in eastern Australia s energy networks', Energies, 14 (2021) [C1] The energy transition for a net-zero future will require deep decarbonisation that hydrogen is uniquely positioned to facilitate. This technoeconomic study considers renewable hyd... [more] The energy transition for a net-zero future will require deep decarbonisation that hydrogen is uniquely positioned to facilitate. This technoeconomic study considers renewable hydrogen production, transmission and storage for energy networks using the National Electricity Market (NEM) region of Eastern Australia as a case study. Plausible growth projections are developed to meet domestic demands for gas out to 2040 based on industry commitments and scalable technology deployment. Analysis using the discounted cash flow technique is performed to determine possible levelised cost figures for key processes out to 2050. Variables include geographic limitations, growth rates and capacity factors to minimise abatement costs compared to business-as-usual natural gas forecasts. The study provides an optimistic outlook considering renewable power-to-X opportunities for blending, replacement and gas-to-power to show viable pathways for the gas transition to green hydrogen. Blending is achievable with modest (3%) green premiums this decade, and substitution for natural gas combustion in the long-term is likely to represent an abatement cost of AUD 18/tCO2-e including transmission and storage.
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2021 |
Islam F, Wang J, Tahmasebi A, Wang R, Moghtaderi B, Yu J, 'Microwave-assisted coal-derived few-layer graphene as an anode material for lithium-ion batteries', Materials, 14 (2021) [C1] A few-layer graphene (FLG) composite material was synthesized using a rich reservoir and low-cost coal under the microwave-assisted catalytic graphitization process. X-ray diffrac... [more] A few-layer graphene (FLG) composite material was synthesized using a rich reservoir and low-cost coal under the microwave-assisted catalytic graphitization process. X-ray diffraction, Raman spectroscopy, transmission electron microscopy, and X-ray photoelectron spectroscopy were used to evaluate the properties of the FLG sample. A well-developed microstructure and higher graphitization degree were achieved under microwave heating at 1300¿ C using the S5% dual (Fe-Ni) catalyst for 20 min. In addition, the synthesized FLG sample encompassed the Raman spectrum 2D band at 2700 cm-1, which showed the existence of a few-layer graphene structure. The high-resolution TEM (transmission electron microscopy) image investigation of the S5% Fe-Ni sample confirmed that the fabricated FLG material consisted of two to seven graphitic layers, promoting the fast lithium-ion diffusion into the inner surface. The S5% Fe-Ni composite material delivered a high reversible capacity of 287.91 mAhg-1 at 0.1 C with a higher Coulombic efficiency of 99.9%. In contrast, the single catalyst of S10% Fe contained a reversible capacity of 260.13 mAhg-1 at 0.1 C with 97.96% Coulombic efficiency. Furthermore, the dual catalyst-loaded FLG sample demonstrated a high capacity¿up to 95% of the initial reversible capacity retention¿after 100 cycles. This study revealed the potential feasibility of producing FLG materials from bituminous coal used in a broad range as anode materials for lithium-ion batteries (LIBs).
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2021 |
Barma MC, Peng Z, Moghtaderi B, Doroodchi E, 'Freeze desalination of drops of saline solutions', Desalination, 517 115265-115265 (2021) [C1]
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Nova | |||||||||
2021 |
Gai S, Peng Z, Moghtaderi B, Yu J, Doroodchi E, 'A theoretical model for predicting homogeneous ice nucleation rate based on molecular kinetic energy distribution', Journal of Molecular Liquids, 333 (2021) [C1]
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Nova | |||||||||
2021 |
Peng Z, Gai S, Barma M, Rahman MM, Moghtaderi B, Doroodchi E, 'Experimental study of gas-liquid-solid flow characteristics in slurry Taylor flow-based multiphase microreactors', Chemical Engineering Journal, 405 (2021) [C1]
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Nova | |||||||||
2021 |
Barma MC, Peng Z, Moghtaderi B, Doroodchi E, 'Effects of drop size and salt concentration on the freezing temperature of supercooled drops of salt solutions', SEPARATION AND PURIFICATION TECHNOLOGY, 274 (2021) [C1]
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Nova | |||||||||
2021 |
Wu S, Zhou C, Tremain P, Doroodchi E, Moghtaderi B, 'A phase change calcium looping thermochemical energy storage system based on CaCO3/CaO-CaCl2', Energy Conversion and Management, 227 (2021) [C1]
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Nova | |||||||||
2021 |
Peng Z, Zanganeh J, Ingle R, Nakod P, Fletcher DF, Moghtaderi B, 'CFD Investigation of Flame and Pressure Wave Propagation through Variable Concentration Methane-Air Mixtures in a Tube Closed at One End', Combustion Science and Technology, 193 1203-1230 (2021) [C1] CFD modeling of methane-air combustion and the subsequent flame and pressure wave propagations from the closed end of a detonation tube is presented, with a focus on propagation t... [more] CFD modeling of methane-air combustion and the subsequent flame and pressure wave propagations from the closed end of a detonation tube is presented, with a focus on propagation through variable concentration mixtures. A partially premixed combustion model that avoids the need to specify the flame speed is developed based upon the Flamelet Generated Manifold (FGM) model and needs no tuning to account for different methane concentrations. The numerical model is extensively validated using the experimental data collected from a large-scale detonation tube. The results show that the pressure wave propagation experiences three sequential stages: i) growth; ii) decoupling; and iii) decay. The peak overpressure is generated in the pressure wave growth stage in which the wave front transiently couples with the flame front, and the confined tube walls induce lateral wave reflections and force the flame front to transit from spherical to planar. Subsequently, the wave front starts decoupling from the flame front, with an almost constant global maximum pressure. After decoupling, the global maximum pressure drops because of the energy loss incurred through the wave propagation. The different methane concentrations introduced initially after the explosion chamber containing a stoichiometric mixture do not affect the peak overpressure or the pressure wave propagation but do affect the profile and propagation of the flame. Exponential acceleration of the flame propagation speed is found in the growth stage of pressure wave propagation, followed by the transition to a linear acceleration stage. For cases with the methane concentration becoming smaller than the stoichiometric concentration, the linear flame acceleration rate is smaller, with more pronounced flame stretching.
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2020 |
Jalalabadi T, Drewery M, Tremain P, Wilkinson J, Moghtaderi B, Allen J, 'The impact of carbonate salts on char formation and gas evolution during the slow pyrolysis of biomass, cellulose, and lignin', SUSTAINABLE ENERGY & FUELS, 4 5987-6003 (2020) [C1]
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2020 |
Albatayneh A, Alterman D, Page A, Moghtaderi B, 'The significance of sky temperature in the assessment of the thermal performance of buildings', Applied Sciences (Switzerland), 10 1-16 (2020) [C1] Energy-efficient building design needs an accurate way to estimate temperature inside the building which facilitates the calculation of heating and cooling energy requirements in ... [more] Energy-efficient building design needs an accurate way to estimate temperature inside the building which facilitates the calculation of heating and cooling energy requirements in order to achieve appropriate thermal comfort for occupants. Sky temperature is an important factor for any building assessment tool which needs to be precisely determined for accurate estimation of the energy requirement. Many building simulation tools have been used to calculate building thermal performance such as Autodesk Computational Fluid Dynamics (CFD) software, which can be used to calculate building internal air temperature but requires sky temperature as a key input factor for the simulation. Real data obtained from real-sized house modules located at University of Newcastle, Australia (southern hemisphere), were used to find the impact of different sky temperatures on the building¿s thermal performance using CFD simulation. Various sky temperatures were considered to determine the accurate response which aligns with a real trend of buildings¿ internal air temperature. It was found that the internal air temperature in a building keeps either rising or decreasing if higher or lower sky temperature is chosen. This significantly decreases the accuracy of the simulation. It was found that using the right sky temperature values for each module, Cavity Brick Module (CB) Insulated Cavity Brick Module (InsCB), Insulated Brick Veneer Module (InsBV) and Insulated Reverse Brick Veneer Module (InsRBV), will result in 6.5%, 7.1%, 6.2% and 6.4% error correspondingly compared with the real data. These errors mainly refer to the simulation error. On the other hand using higher sky temperatures by +10¿C will significantly increase the simulation error to 16.5%, 17.5%, 17.1% and 16.8% and lower sky temperature by +10¿C will also increase the error to 19.3%, 22.6%, 21.9% and 19.1% for CB, InsCB, InsBV and InsRBV modules, respectively.
|
Nova | |||||||||
2020 |
Peng Z, Doroodchi E, Moghtaderi B, 'Heat transfer modelling in Discrete Element Method (DEM)-based simulations of thermal processes: Theory and model development', Progress in Energy and Combustion Science, 79 (2020) [C1]
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Nova | |||||||||
2020 |
Rahman SMA, Tahmasebi A, Moghtaderi B, Yu J, 'Kinetics and Mechanism of Catalytic Oxidation of NO in Coal Combustion Flue Gas over Co-Doped Mn-Ti Oxide Catalyst', ENERGY & FUELS, 34 6052-6058 (2020) [C1]
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2020 |
Gurieff N, Green D, Koskinen I, Lipson M, Baldry M, Maddocks A, et al., 'Healthy power: Reimagining hospitals as sustainable energy hubs', Sustainability (Switzerland), 12 1-17 (2020) [C1] Human health is a key pillar of modern conceptions of sustainability. Humanity pays a considerable price for its dependence on fossil-fueled energy systems, which must be addresse... [more] Human health is a key pillar of modern conceptions of sustainability. Humanity pays a considerable price for its dependence on fossil-fueled energy systems, which must be addressed for sustainable urban development. Public hospitals are focal points for communities and have an opportunity to lead the transition to renewable energy. We have reimagined the healthcare energy ecosystem with sustainable technologies to transform hospitals into networked clean energy hubs. In this concept design, hydrogen is used to couple energy with other on-site medical resource demands, and vanadium flow battery technology is used to engage the public with energy systems. This multi-generation system would reduce harmful emissions while providing reliable services, tackling the linked issues of human and environmental health.
|
Nova | |||||||||
2020 |
Guan L, Yuan Z, Moghtaderi B, Peng Z, Evans GM, Gu C, Doroodchi E, 'Prediction of terminal velocity of fractal aggregates with IBM-LBM method', POWDER TECHNOLOGY, 361 1060-1069 (2020) [C1]
|
Nova | |||||||||
2020 |
Zanganeh J, Al-Zuraiji MJA, Moghtaderi B, 'Capture and Mitigation of Fugitive Methane: Examining the Characteristics of Methane Explosions in an Explosion Chamber Connected to a Venting Duct', ENERGY & FUELS, 34 645-654 (2020) [C1]
|
Nova | |||||||||
2020 |
Nadaraju FJ, Maddocks AR, Zanganeh J, Moghtaderi B, 'Ventilation air methane: a simulation of an optimised process of abatement with power and cooling', Mining Technology: Transactions of the Institute of Mining and Metallurgy, 129 9-21 (2020) [C1]
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Nova | |||||||||
2020 |
Albatayneh A, Alterman D, Page A, Moghtaderi B, 'Alternative method to the replication of wind effects into the buildings thermal simulation', Buildings, 10 1-17 (2020) [C1] To design energy-efficient buildings, energy assessment programs need to be developed for determining the inside air temperature, so that thermal comfort of the occupant can be su... [more] To design energy-efficient buildings, energy assessment programs need to be developed for determining the inside air temperature, so that thermal comfort of the occupant can be sustained. The internal temperatures could be calculated through computational fluid dynamics (CFD) analysis; however, miniscule time steps (seconds and milliseconds) are used by a long-term simulation (i.e., weeks, months) that require excessive time for computing wind effects results even for high-performance personal computers. This paper examines a new method, wherein the wind effect surrounding the buildings is integrated with the external air temperature to facilitate wind simulation in building analysis over long periods. This was done with the help of an equivalent temperature (known as Tnatural ), where the convection heat loss is produced in an equal capacity by this air temperature and by the built-in wind effects. Subsequently, this new external air temperature Tnatural can be used to calculate the internal air temperature. Upon inclusion of wind effects, above 90% of the results were found to be within 0¿3¿C of the perceived temperatures compared to the real data (99% for insulated cavity brick (InsCB), 91% for cavity brick (CB), 93% for insulated reverse brick veneer (InsRBV) and 94% for insulated brick veneer (InsBV) modules). However, a decline of 83¿88% was observed in the results after ignoring the wind effects. Hence, the presence of wind effects holds greater importance in correct simulation of the thermal performance of the modules. Moreover, the simulation time will expectedly reduce to below 1% of the original simulation time.
|
Nova | |||||||||
2020 |
Peng Z, Ge L, Moreno-Atanasio R, Evans G, Moghtaderi B, Doroodchi E, 'VOF-DEM study of solid distribution characteristics in slurry Taylor flow-based multiphase microreactors', Chemical Engineering Journal, 396 (2020) [C1]
|
Nova | |||||||||
2020 |
Gai S, Peng Z, Moghtaderi B, Yu J, Doroodchi E, 'LBM modelling of supercooled water freezing with inclusion of the recalescence stage', International Journal of Heat and Mass Transfer, 146 (2020) [C1]
|
Nova | |||||||||
2020 |
Jalalabadi T, Moghtaderi B, Allen J, 'Thermochemical Conversion of Biomass in the Presence of Molten Alkali-Metal Carbonates under Reducing Environments of N2 and CO2', Energies, 13 (2020) [C1]
|
Nova | |||||||||
2020 |
Peng Z, Zanganeh J, Ingle R, Nakod P, Fletcher DF, Moghtaderi B, 'Effect of Tube Size on Flame and Pressure Wave Propagation in a Tube Closed at One End: A Numerical Study', Combustion Science and Technology, 192 1731-1753 (2020) [C1]
|
Nova | |||||||||
2020 |
Wu S, Zhou C, Doroodchi E, Moghtaderi B, 'Techno-economic analysis of an integrated liquid air and thermochemical energy storage system', Energy Conversion and Management, 205 (2020) [C1]
|
Nova | |||||||||
2019 |
Tremain P, Maddocks A, Moghtaderi B, 'Stone Dust Looping for Ventilation Air Methane Abatement: A 1 m³/s Pilot-Scale Study', Energy and Fuels, 33 12568-12577 (2019) [C1]
|
Nova | |||||||||
2019 |
Peng Z, Zanganeh J, Doroodchi E, Moghtaderi B, 'Flame Propagation and Reflections of Pressure Waves through Fixed Beds of RTO Devices: A CFD Study', Industrial and Engineering Chemistry Research, 58 23389-23404 (2019) [C1]
|
Nova | |||||||||
2019 |
Wu S, Zhou C, Doroodchi E, Moghtaderi B, 'Thermodynamic analysis of a novel hybrid thermochemical-compressed air energy storage system powered by wind, solar and/or off-peak electricity', Energy Conversion and Management, 180 1268-1280 (2019) [C1]
|
Nova | |||||||||
2019 |
Albatayneh A, Alterman D, Page A, Moghtaderi B, 'The significance of the adaptive thermal comfort limits on the air-conditioning loads in a temperate climate', Sustainability, 11 (2019) [C1]
|
Nova | |||||||||
2019 |
AL-Zuraiji MJA, Zanganeh J, Moghtaderi B, 'Application of flame arrester in mitigation of explosion and flame deflagration of ventilation air methane', Fuel, 257 (2019) [C1]
|
Nova | |||||||||
2019 |
Albatayneh A, Alterman D, Page A, Moghtaderi B, 'Development of a new metric to characterise the buildings thermal performance in a temperate climate', Energy for Sustainable Development, 51 1-12 (2019) [C1]
|
Nova | |||||||||
2019 |
Nadaraju FJ, Maddocks AR, Zanganeh J, Moghtaderi B, 'Simulation of power and cooling generation via heat recovery from a ventilation air methane abatement unit', Fuel, 249 27-35 (2019) [C1]
|
Nova | |||||||||
2019 |
Lee S, Yu J, Mahoney M, Tremain P, Moghtaderi B, Tahmasebi A, et al., 'Study of chemical structure transition in the plastic layers sampled from a pilot-scale coke oven using a thermogravimetric analyzer coupled with Fourier transform infrared spectrometer', Fuel, 242 277-286 (2019) [C1]
|
Nova | |||||||||
2019 |
Alghamdi Y, Peng Z, Zanganeh J, Moghtaderi B, Doroodchi E, 'Hydrodynamics similarities in cold flow model of chemical looping combustors: An experimental study', Powder Technology, 343 542-550 (2019) [C1]
|
Nova | |||||||||
2019 |
Khairul MA, Zanganeh J, Moghtaderi B, 'The composition, recycling and utilisation of Bayer red mud', Resources, Conservation and Recycling, 141 483-498 (2019) [C1]
|
Nova | |||||||||
2019 |
Alghamdi YA, Peng Z, Luo C, Almutairi Z, Moghtaderi B, Doroodchi E, 'Systematic Study of Pressure Fluctuation in the Riser of a Dual Inter-Connected Circulating Fluidized Bed: Using Single and Binary Particle Species', PROCESSES, 7 (2019) [C1]
|
Nova | |||||||||
2019 |
Fan F, Zhang S, Peng Z, Chen J, Su M, Moghtaderi B, Doroodchi E, 'Numerical investigation of heterogeneous nucleation of water vapour on PM10 for particulate abatement', Canadian Journal of Chemical Engineering, 97 930-939 (2019) [C1]
|
Nova | |||||||||
2019 |
Jalalabadi T, Glenn M, Tremain P, Moghtaderi B, Donne S, Allen J, 'Modification of Biochar Formation during Slow Pyrolysis in the Presence of Alkali Metal Carbonate Additives', ENERGY & FUELS, 33 11235-11245 (2019) [C1]
|
Nova | |||||||||
2019 |
Wu S, Zhou C, Doroodchi E, Moghtaderi B, 'A unique phase change redox cycle using CuO/Cu2 O for utility-scale energy storage', Energy Conversion and Management, 188 366-380 (2019) [C1]
|
Nova | |||||||||
2018 |
Kundu SK, Zanganeh J, Eschebach D, Badat Y, Moghtaderi B, 'Confined explosion of methane-air mixtures under turbulence', Fuel, 220 471-480 (2018) [C1]
|
Nova | |||||||||
2018 |
Sun S, Yuan Z, Peng Z, Moghtaderi B, Doroodchi E, 'Computational investigation of particle flow characteristics in pressurised dense phase pneumatic conveying systems', Powder Technology, 329 241-251 (2018) [C1]
|
Nova | |||||||||
2018 |
Ramezani M, Tremain P, Shah K, Doroodchi E, Moghtaderi B, 'Kinetics and Design Parameter Determination for a Calciner Reactor in Unique Conditions of a Novel Greenhouse Calcium Looping Process', ENERGY & FUELS, 32 33-43 (2018) [C1]
|
Nova | |||||||||
2018 |
Momenzadeh L, Moghtaderi B, Belova I, Murch GE, 'Determination of the lattice thermal conductivity of the TiO2 polymorphs rutile and anatase by molecular dynamics simulation', COMPUTATIONAL CONDENSED MATTER, 17 (2018) [C1]
|
Nova | |||||||||
2018 |
Albatayneh A, Alterman D, Page A, Moghtaderi B, 'The Significance of Building Design for the Climate', Environmental and Climate Technologies, 22 165-178 (2018) [C1]
|
Nova | |||||||||
2018 |
Yin F, Tremain P, Yu J, Doroodchi E, Moghtaderi B, 'An Experimental Investigation of the Catalytic Activity of Natural Calcium-Rich Minerals and a Novel Dual-Supported CaO-Ca12Al14O33/Al2O3 Catalyst for Biotar Steam Reforming', ENERGY & FUELS, 32 4269-4277 (2018) [C1]
|
Nova | |||||||||
2018 |
Lee S, Yu J, Mahoney M, Tremain P, Moghtaderi B, Tahmasebi A, 'A study on the structural transition in the plastic layer during coking of Australian coking coals using Synchrotron micro-CT and ATR-FTIR', Fuel, 233 877-884 (2018) [C1]
|
Nova | |||||||||
2018 |
Nadaraju FJ, Maddocks AR, Zanganeh J, Moghtaderi B, 'Thermodynamic Assessment of Heat Recovery from a Fluidized-Bed Ventilation Air Methane Abatement Unit', ENERGY & FUELS, 32 4579-4585 (2018) [C1]
|
Nova | |||||||||
2018 |
Wu S, Zhou C, Doroodchi E, Nellore R, Moghtaderi B, 'A review on high-temperature thermochemical energy storage based on metal oxides redox cycle', Energy Conversion and Management, 168 421-453 (2018) [C1]
|
Nova | |||||||||
2018 |
Wilson F, Tremain P, Moghtaderi B, 'Characterization of Biochars Derived from Pyrolysis of Biomass and Calcium Oxide Mixtures', ENERGY & FUELS, 32 4167-4177 (2018) [C1]
|
Nova | |||||||||
2018 |
Kundu SK, Zanganeh J, Eschebach D, Moghtaderi B, 'Explosion severity of methane coal dust hybrid mixtures in a ducted spherical vessel', Powder Technology, 323 95-102 (2018) [C1]
|
Nova | |||||||||
2018 |
Ajrash MJ, Zanganeh J, Moghtaderi B, 'Flame deflagration in side-on vented detonation tubes: a large scale study', Journal of Hazardous Materials, 345 38-47 (2018) [C1]
|
Nova | |||||||||
2018 |
Momenzadeh L, Moghtaderi B, Buzzi O, Liu X, Sloan SW, Murch GE, 'The thermal conductivity decomposition of calcite calculated by molecular dynamics simulation', COMPUTATIONAL MATERIALS SCIENCE, 141 170-179 (2018) [C1]
|
Nova | |||||||||
2018 |
Luo C, Peng Z, Doroodchi E, Moghtaderi B, 'A three-dimensional hot flow model for simulating the alumina encapsulated NI-NIO methane-air CLC system based on the computational fluid dynamics-discrete element method', Fuel, 224 388-400 (2018) [C1] A three-dimensional hot flow model for simulating the alumina encapsulated Ni/NiO methane-air CLC system is developed. The temperature of particles (i.e., metal/metal oxides) is c... [more] A three-dimensional hot flow model for simulating the alumina encapsulated Ni/NiO methane-air CLC system is developed. The temperature of particles (i.e., metal/metal oxides) is calculated based on exothermal/endothermal reactions and the convective heat transfer between particles and the gas mixture. The temperature of the gas mixture is solved by incorporating the energy exchange with the oxygen carrier particles into the governing equations. The motion of particles is tracked using the discrete element method, whilst the fluid flow is governed by the modified Navier-Stokes equations derived by replacing the point and fluid mechanical variables with locally averaged variables and the inclusion of local gas volume fraction. Two different CLC systems with different initial particle conversion rates have been simulated and the characteristics of the CLC hot flow system in terms of distributions of particle and gas mixture temperatures, solid circulation rate and particle conversion rate have been analysed and discussed. The results showed that the transient solid circulation rate varied but fluctuated around a certain value. Heterogeneous distributions of particle temperature and conversion rate have been observed in both fuel and air reactors. The model has been validated by comparing the predicted solid circulation rate and pressure distribution against the experimental data. The hot flow model proves capable of reproducing the CLC mechanism, i.e., transferring oxygen atom from the air reactor to the fuel reactor.
|
Nova | |||||||||
2018 |
Patel S, Tremain P, Moghtaderi B, Sandford J, Shah K, 'Estimation of the carbonation reaction kinetic parameters for dilute methane and carbon dioxide conditions in a calcium looping process', Environmental Progress and Sustainable Energy, 37 1312-1318 (2018) [C1]
|
Nova | |||||||||
2018 |
Albatayneh A, Alterman D, Page A, Moghtaderi B, 'The impact of the thermal comfort models on the prediction of building energy consumption', Sustainability (Switzerland), 10 (2018) [C1]
|
Nova | |||||||||
2017 |
Peng Z, Moghtaderi B, Doroodchi E, 'A simple model for predicting solid concentration distribution in binary-solid liquid fluidized beds', AICHE JOURNAL, 63 469-484 (2017) [C1]
|
Nova | |||||||||
2017 |
To TQ, Shah K, Tremain P, Simmons BA, Moghtaderi B, Atkin R, 'Treatment of lignite and thermal coal with low cost amino acid based ionic liquid-water mixtures', FUEL, 202 296-306 (2017) [C1]
|
Nova | |||||||||
2017 |
Zhou C, Tremain P, Doroodchi E, Moghtaderi B, Shah K, 'A novel slag carbon arrestor process for energy recovery in steelmaking industry', Fuel Processing Technology, 155 124-133 (2017) [C1] A novel slag carbon arrestor process (SCAP) was proposed to improve the heat recovery in energy-intensive steelmaking process, which typically has a low heat recovery. The propose... [more] A novel slag carbon arrestor process (SCAP) was proposed to improve the heat recovery in energy-intensive steelmaking process, which typically has a low heat recovery. The proposed SCAP process introduces a tar reformer to utilise the slag - a by-product from steelmaking process - as the catalyst to convert coke oven gas and tar into hydrogen-enriched fuel gas. This is achieved by making use of the valuable carbon and/or energy contained in the coke oven gas, which otherwise being wasted, to assist in tar reforming and produce hydrogen-enriched gas. Such concept is expected to reduce the undesired tar formation in steelmaking process along with improved heat recovery efficiency and higher quality coke oven gas production. Both simulation and experimental studies on the slag carbon arrestor process were performed. The preliminary thermodynamic analysis carried out using Aspen Plus v8.4 indicates that with the tar reformer the energy content of coke oven gas was found increased from ~ 34.6 MJ/kg to ~ 37.7 MJ/kg (or by 9%). Also, with the utilisation of carbon deposition on the slag, a reduction of up to 12.8% coke usage in the steelmaking process can be achieved. This corresponds to an energy saving of 4% and a carbon emission reduction of 5.7% compared with the conventional steelmaking process. Preliminary experimental TGA-FTIR investigations revealed a reduction in the aromatic and aliphatic hydrocarbon groups and an increase in the production of CO2 and CO, attributed to the tar cracking abilities of slag.
|
Nova | |||||||||
2017 |
Ajrash MJ, Zanganeh J, Moghtaderi B, 'Deflagration of premixed methane air in a large scale detonation tube', Process Safety and Environmental Protection, 109 374-386 (2017) [C1]
|
Nova | |||||||||
2017 |
Paymooni K, Doroodchi E, Moghtaderi B, 'Oxygen adsorption and desorption characteristics of LSCF5582 membranes for oxygen separation applications', ADVANCED POWDER TECHNOLOGY, 28 1531-1539 (2017) [C1]
|
Nova | |||||||||
2017 |
Ghatage SV, Khan MS, Peng Z, Doroodchi E, Moghtaderi B, Padhiyar N, et al., 'Settling/rising of a foreign particle in solid-liquid fluidized beds: Application of dynamic mesh technique', CHEMICAL ENGINEERING SCIENCE, 170 139-153 (2017) [C1]
|
Nova | |||||||||
2017 |
Kundu SK, Zanganeh J, Eschebach D, Mahinpey N, Moghtaderi B, 'Explosion characteristics of methane air mixtures in a spherical vessel connected with a duct', Process Safety and Environmental Protection, 111 85-93 (2017) [C1]
|
Nova | |||||||||
2017 |
Khairul MA, Doroodchi E, Azizian R, Moghtaderi B, Alam M, 'Advanced applications of tunable ferrofluids in energy systems and energy harvesters: A critical review', Energy Conversion and Management, 149 660-674 (2017) [C1]
|
Nova | |||||||||
2017 |
Shiel JJ, Aynsley R, Moghtaderi B, Page A, 'The importance of air movement in warmer temperatures: a novel SET* house case study', ARCHITECTURAL SCIENCE REVIEW, 60 225-238 (2017) [C1]
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2017 |
Peng Z, Moghtaderi B, Doroodchi E, 'Suspension stability of slurry Taylor flow: A theoretical analysis', CHEMICAL ENGINEERING SCIENCE, 174 459-471 (2017) [C1]
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2017 |
Paymooni K, Doroodchi E, Motuzas J, da Costa JCD, Moghtaderi B, 'Feasibility study of LSCF5582 membrane integration into a nitrogen based chemical looping air separation process', Chemical Engineering Research and Design, 125 96-107 (2017) [C1] This study investigates the suitability and effectiveness of La0.5Sr0.5Co0.8Fe0.2O3-d (LSCF5582) membrane for integration into the reduction reactor of a Nitrogen based chemical l... [more] This study investigates the suitability and effectiveness of La0.5Sr0.5Co0.8Fe0.2O3-d (LSCF5582) membrane for integration into the reduction reactor of a Nitrogen based chemical looping air separation (CLAS) process for exclusive separation of oxygen. First, the structural and chemical characteristics as well as the oxygen separation properties of LSCF5582 membranes, prepared at sintering temperatures of 1050¿1350¿°C, were examined to obtain the optimum range of sintering temperatures resulting in membranes with enhanced oxygen separation from air. This was achieved by determining the oxygen permeation properties of LSCF5582 membranes under the reducing environment of the Nitrogen based CLAS process, whereby oxygen is liberated from CuO oxygen carriers on the feed side of the membrane using nitrogen as a reducing gas. Membrane characterisation results showed that a single phase dense LSCF5582 membrane was formed at the sintering temperature range of 1200¿1225¿°C obtaining a maximum oxygen permeation flux of 0.67¿ml¿min-1¿cm-2 and oxygen recovery of 27% at the sintering and operating temperatures of 1200¿°C and 900¿°C, respectively. At the same operating temperature, under the reducing environment of nitrogen, the LSCF5582 membrane sintered at 1225¿°C was found to perform best achieving an oxygen permeation flux and oxygen recovery of 0.77¿ml¿min-1¿cm-2 and 76%, respectively.
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2017 |
Aqsha A, Tijani MM, Moghtaderi B, Mahinpey N, 'Catalytic pyrolysis of straw biomasses (wheat, flax, oat and barley) and the comparison of their product yields', JOURNAL OF ANALYTICAL AND APPLIED PYROLYSIS, 125 201-208 (2017) [C1]
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2017 |
Yin F, Tremain P, Yu J, Doroodchi E, Moghtaderi B, 'Investigations on the Synergistic Effects of Oxygen and CaO for Biotars Cracking during Biomass Gasification', ENERGY & FUELS, 31 587-598 (2017) [C1]
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2017 |
Cummings J, Tremain P, Shah K, Heldt E, Moghtaderi B, Atkin R, et al., 'Modification of lignites via low temperature ionic liquid treatment', FUEL PROCESSING TECHNOLOGY, 155 51-58 (2017) [C1]
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2017 |
Ajrash MJ, Zanganeh J, Moghtaderi B, 'The effects of coal dust concentrations and particle sizes on the minimum auto-ignition temperature of a coal dust cloud', Fire and Materials, 41 908-915 (2017) [C1]
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2017 |
Khairul MA, Doroodchi E, Azizian R, Moghtaderi B, Alam M, 'Thermal performance analysis of tunable magnetite nanofluids for an energy system', APPLIED THERMAL ENGINEERING, 126 822-833 (2017) [C1]
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2017 |
Albatayneh A, Alterman D, Page A, Moghtaderi B, 'The Significance of Temperature Based Approach Over the Energy Based Approaches in the Buildings Thermal Assessment', ENVIRONMENTAL AND CLIMATE TECHNOLOGIES, 19 39-50 (2017) [C1]
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2017 |
Ajrash MJ, Zanganeh J, Moghtaderi B, 'The flame deflagration of hybrid methane coal dusts in a large-scale detonation tube (LSDT)', FUEL, 194 491-502 (2017) [C1]
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2017 |
Ajrash MJ, Zanganeh J, Moghtaderi B, 'Impact of suspended coal dusts on methane deflagration properties in a large-scale straight duct', JOURNAL OF HAZARDOUS MATERIALS, 338 334-342 (2017) [C1]
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2017 |
Khairul MA, Doroodchi E, Azizian R, Moghtaderi B, 'The influence of different flow regimes on heat transfer performance and exergy loss of Al2O3/DI-water and CuO/DI-water nanofluids', APPLIED THERMAL ENGINEERING, 122 566-578 (2017) [C1]
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2017 |
Ramezani M, Tremain P, Shah K, Doroodchi E, Moghtaderi B, 'Derivation of Kinetics and Design Parameters for a Carbonator Reactor in a Greenhouse Calcium Looping Process', ENERGY TECHNOLOGY, 5 644-655 (2017) [C1]
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2017 |
Fan F, Zhang M, Peng Z, Chen J, Su M, Moghtaderi B, Doroodchi E, 'Direct Simulation Monte Carlo Method for Acoustic Agglomeration under Standing Wave Condition', AEROSOL AND AIR QUALITY RESEARCH, 17 1073-1083 (2017) [C1]
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2017 |
Khan MD, Evans GM, Peng Z, Doroodchi E, Moghtaderi B, Joshi JB, et al., 'Expansion behaviour of a binary solid-liquid fluidised bed with different solid mass ratio', ADVANCED POWDER TECHNOLOGY, 28 3111-3129 (2017) [C1]
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2017 |
Ajrash MJ, Zanganeh J, Moghtaderi B, 'Experimental evaluation and analysis of methane fire and explosion mitigation using isolation valves integrated with a vent system', Journal of Hazardous Materials, 339 301-309 (2017) [C1] There has been a surge of interest from the extractive industries in the application of mechanical means to the mitigation of flame deflagration. To verify the implementation and ... [more] There has been a surge of interest from the extractive industries in the application of mechanical means to the mitigation of flame deflagration. To verify the implementation and performance of passive and active mitigation protection, a comprehensive experimental investigation has been conducted on a large scale detonation tube, 30¿m long and 0.5¿m in diameter, with two mitigation valves (passive and active) and a burst panel venting system. The valves were used alternately to mitigate the flame deflagration of methane in concentrations ranging from 1.25% to 7.5%. The experimental work revealed that locating the passive mitigation valve at 22¿m distance from the ignition source mitigates the flame by fully isolating the tube. However, closing the valve structure in the axial direction generated another pressure wave upstream, which was approximately the same value as for the original pressure wave upstream. In the case of the active mitigation system, the system perfectly isolated upstream from downstream with no further pressure wave generation. When the vent was located at 6.5¿m from the ignition source, the total pressure was reduced by 0.48¿bar. Due to the counter flow of the reflected pressure wave the flame was extinguished at 12.5¿m from the ignition source.
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2017 |
Ajrash MJ, Zanganeh J, Moghtaderi B, 'Influences of the Initial Ignition Energy on Methane Explosion in a Flame Deflagration Tube', ENERGY & FUELS, 31 6422-6434 (2017) [C1]
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2016 |
Patel S, Tremain P, Sandford J, Moghtaderi B, Shah K, 'Empirical Kinetic Model of a Stone Dust Looping Carbonator for Ventilation Air Methane Abatement', ENERGY & FUELS, 30 1869-1878 (2016) [C1]
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2016 |
Yin F, Shah K, Zhou C, Tremain P, Yu J, Doroodchi E, Moghtaderi B, 'Novel Calcium-Looping-Based Biomass-Integrated Gasification Combined Cycle: Thermodynamic Modeling and Experimental Study', Energy and Fuels, 30 1730-1740 (2016) [C1] The current work focuses on the development of a novel calcium-looping-based biomass-integrated gasification combined cycle (CL-BIGCC) process. The process is expected to improve ... [more] The current work focuses on the development of a novel calcium-looping-based biomass-integrated gasification combined cycle (CL-BIGCC) process. The process is expected to improve the energy density of synthesis gas by capturing CO2 in a carbonator. Also, at the same time, the carbonator is expected to act as an ex situ tar removal unit, where tar cracking is expected to occur via catalytic reactions with CaO. The current work evaluates the feasibility of the proposed CL-BIGCC concept via thermodynamic analysis using Aspen Plus. Moreover, the tar cracking ability of CaO is demonstrated using thermogravimetric analyzer coupled to Fourier transform infrared spectrometer (TGA-FTIR) experiments. As part of the thermodynamic analysis, sensitivity analyses of the key process parameters, such as the calcium/biomass (Ca/B) ratio, steam/biomass (S/B) ratio, carbonator temperature, and calciner temperature, and their effects on net thermal-to-electricity efficiency have been studied in detail. The optimal values of key process parameters, such as a compression ratio of 5.1, an air/fuel mass ratio of 15, a Ca/B ratio of 0.53, a S/B ratio of 0.17, and carbonator and calciner temperatures of 650 and 800 °C, respectively, have been obtained. Furthermore, the CL-BIGCC process simulated in the current work was found to have a net thermal-to-electricity efficiency of ~25% based on the above optimal parameters, which is the highest among other conventional steam-based BIGCC processes. The biomass gasification (i.e., partial oxidation) experiments in a TGA-FTIR with a CaO/biomass ratio of 1:1 at different temperatures showed that CaO effectively catalyzed tar-cracking reactions.
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2016 |
Zhou C, Shah K, Song H, Zanganeh J, Doroodchi E, Moghtaderi B, 'Integration Options and Economic Analysis of an Integrated Chemical Looping Air Separation Process for Oxy-fuel Combustion', Energy and Fuels, 30 1741-1755 (2016) [C1] This paper is concerned about a detailed techno-economic assessment of a hypothetical 500 MWe coal-fired power plant in New South Wales, Australia, for oxy-fuel conversion using i... [more] This paper is concerned about a detailed techno-economic assessment of a hypothetical 500 MWe coal-fired power plant in New South Wales, Australia, for oxy-fuel conversion using integrated chemical looping air separation (ICLAS) technology and cryogenic air separation unit (CASU). The key objectives of this study are to (i) investigate and compare the detailed integration options for oxy-fuel conversion using ICLAS and CASU and (ii) determine the technical merits of the above integration options and the conditions at which the technologies become economically feasible. The study produced scientific evidence that confirms the viability of the CLAS process from both technical and economic points of view under certain conditions. The detailed technical analysis revealed that ICLAS with natural gas integration is energy-efficient compared to CASU running on parasitic load. This is primarily due to the fact that ICLAS needs less auxiliary power compared to CASU. Despite the fact that ICLAS natural gas integration has resulted in higher efficiencies than CASU running on parasitic load, from a series of detailed economic analyses, it was observed that both ICLAS and CASU may not be viable under the present operating and economic conditions. Nevertheless, from sensitivity analysis, it was concluded that ICLAS can become feasible if economic conditions are improved, e.g., a low natural gas market price (<$3.5/GJ), a high electricity wholesale price (>$59/MWh), and/or a high carbon tax (>$33/tonne).
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2016 |
Ajrash MJ, Zanganeh J, Moghtaderi B, 'Methane-coal dust hybrid fuel explosion properties in a large scale cylindrical explosion chamber', Journal of Loss Prevention in the Process Industries, 40 317-328 (2016) [C1] The fires and explosions caused by flammable hydrocarbon air mixtures are a major safety concern in the chemical and processing industries. The thermo-physical and chemical proper... [more] The fires and explosions caused by flammable hydrocarbon air mixtures are a major safety concern in the chemical and processing industries. The thermo-physical and chemical properties of the flammable fuels in a hybrid form appear to have a significant impact on the combustion process. This usually occurs due to substantial changes in the flammability concentration regimes. The aim of this study is to investigate the fire and explosive properties of hybrid fuels in the chemical and process industries. In addition, it examines the impact of the ignition energy and vessel geometry on the magnitude of the pressure rise and flame propagation velocity. The experimental work was conducted on a cylindrically shaped explosion chamber constructed as part of this study at The University of Newcastle, Australia. The chamber was made of mild steel and was 30 m in length and 0.5 in diameter. It included a series of high resolution pressure transducers, a pyrometer, as well as a high speed video camera. Methane and coal dust were used as fuels and chemical igniters with a known energy were used to ignite the fuels.The results obtained from this study showed that both the ignition energy and the diluted combustible fuel dust have significant impacts on the Over Pressure Rise (OPR) in an explosion chamber. The significant findings included that the OPR doubled when 30 g m-3 of coal dust was added to a 6% methane/air mixture, and it increased by 60% when 10 kJ was used instead of a 1 kJ ignition source. The initial ignition energy was observed to considerably enhance the speed of both the pressure wave and the flame front, where the pressure wave speed doubled when using a 5 kJ instead of a 1 kJ ignition source. However, the pressure wave speed increased by five times when a 10 kJ was used instead of a 1 kJ ignition source. Additionally, the maximum flame front velocity observed for the ignition source with 5 kJ energy was twice the flame front velocity for the 1 kJ ignition source. Finally, it was observed that the time needed for the initial methane ignition was reduced by about 50% when using a 10 kJ instead of a 1 kJ ignition source.
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2016 |
Khairul MA, Shah K, Doroodchi E, Azizian R, Moghtaderi B, 'Effects of surfactant on stability and thermo-physical properties of metal oxide nanofluids', International Journal of Heat and Mass Transfer, 98 778-787 (2016) [C1] Optimal thermo-physical properties of nanofluids provide an opportunity to overcome energy associated difficulties, in addition to providing new alternatives to catch, store and e... [more] Optimal thermo-physical properties of nanofluids provide an opportunity to overcome energy associated difficulties, in addition to providing new alternatives to catch, store and exchange of energy. A significant reduction in energy consumption is possible by improving the performance of a heat exchanger circuit, and may in part alleviate current energy related challenging issues such as global warming, climate change, and the fuel crisis. The objective of this work is to gain an insight into the overall stability of nanofluids with respect to pH, zeta potential, particle size distribution, and its effect on viscosity and thermal conductivity. For the purpose of this study two nanofluids were selected (water based alumina and copper oxide). Various nanoparticles concentrations as well as anionic surfactants (sodium dodecylbenzene sulfonate) were investigated for their stability, viscosity as well as thermal conductivity. The results clearly showed that nanofluid stability has a strong relation with viscosity and thermal conductivity. The stability of the nanofluid was found to be improved with a decrease in viscosity and an increase in thermal conductivity.
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2016 |
Ajrash MJ, Zanganeh J, Moghtaderi B, 'Experimental investigation of the minimum auto-ignition temperature (MAIT) of the coal dust layer in a hot and humid environment', Fire Safety Journal, 82 12-22 (2016) [C1] Ventilation Air Methane (VAM) abatement technology is recognized as a promising and value adding technique for reducing fugitive methane emissions, however, it also increases the ... [more] Ventilation Air Methane (VAM) abatement technology is recognized as a promising and value adding technique for reducing fugitive methane emissions, however, it also increases the potential fire and explosion risks of overheated coal dust. To eliminate these risks from the abatement systems it is necessary to determine the critical combustion characteristics of the minimum auto ignition temperature (MAIT) for a coal dust layer. This study investigates the auto-ignition behavior of coal dust layers in a humid environment with Relative Humidity (RH) >80%. The MAIT of four different coal dust samples (Australian coal) with particle sizes below 212 µm and dust layer thicknesses of 5, 12 and 15 mm were measured using a dust layer auto ignition temperature apparatus in accordance with the ASTM E2021 standard. It was concluded that the MAIT of the coal dust layer significantly decreases with decreasing particle size. The MAIT for the coal samples with a smaller D50 size were observed to be lower in comparison with samples with a larger D50 size. The dust layer thickness was shown to significantly impact on the MAIT. The MAIT increased proportionally with the increasing thickness of the coal dust layer. The effect of the coal dust moisture content and humidity on the MAIT for compacted dust layers was noticeable, whereas, this effect was less important with loose dust layers. In addition, this work investigated and compared the MAIT for a typical coal dust sample based on the existing ASTM and International Electrotechnical Commission (IEC) standard procedures for ignition of coal dust layers.
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2016 |
Alghamdi Y, Peng Z, shah K, Moghtaderi B, Doroodchi E, 'A correlation for predicting solids holdup in the dilute pneumatic conveying flow regime of circulating and interconnected fluidised beds', Powder Technology, 297 357-366 (2016) [C1] Theoretical modelling, design and operation of circulating and interconnected fluidized beds require an accurate prediction of solids holdup in the fully developed pneumatic conve... [more] Theoretical modelling, design and operation of circulating and interconnected fluidized beds require an accurate prediction of solids holdup in the fully developed pneumatic conveying flow regime of the riser (i.e. the upper section of the riser). Existing empirical and semi-empirical solids holdup correlations have exhibited limited accuracy and application range. In this study, an empirical correlation was developed to predict the solids holdup at the upper section of the riser in circulating and interconnected fluidized beds with an improved level of accuracy for a broad range of operating conditions and riser dimensions. The correlation is based on a group of dimensionless quantities, which are typically used to describe the hydrodynamics of gas-solids fluidized beds, taking into account gas and particle properties, riser dimensions, and solid circulation rate. The reduced solids flux phenomenon also has been considered directly by introducing a system dependent exponent in the correlation. The correlation predicted 90% of the experimental data with an average deviation of 15%. The correlation is applicable for particle Reynolds numbers between 3.7 and 366.
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2016 |
Peng Z, Alghamdi YA, Moghtaderi B, Doroodchi E, 'CFD-DEM investigation of transition from segregation to mixing of binary solids in gas fluidised beds', Advanced Powder Technology, 27 2342-2353 (2016) [C1] Gas-solid fluidised beds are widely used in chemical, petrochemical, pharmaceutical, biochemical and powder industries. Particles used in gas-solid fluidised beds often differ in ... [more] Gas-solid fluidised beds are widely used in chemical, petrochemical, pharmaceutical, biochemical and powder industries. Particles used in gas-solid fluidised beds often differ in size and/or density, thus have the tendency to segregate under certain operating conditions. The results of our earlier work (Alghamdi et al., 2013) showed that for a given binary mixture, the transition from segregation to mixing occurred when the superficial gas velocity was increased over a critical value. In this study, force analysis at particle scale, including particle-particle, particle-wall and particle-fluid interacting forces, has been performed to investigate the underlying mechanisms that drive the occurrence of the transition. The results showed that as the superficial gas velocity increased, the system exhibited three sequential states: segregated, transition, and mixed. The vertical fluid force acting on the particles was found to be responsible for the occurrence of the transition from segregation to mixing, at which the bulk density of the heavy (small) particle species became smaller than the actual density of the light (large) species. After the occurrence of the transition, the particle collisional effects were dominant over the fluid viscous effects in governing the gas-solid two-phase flow. After the system became mixed, the net force of fluid and particle net weight forces conversely tended to separate the particles. However, the particle dispersion induced by particle collisions counterbalanced the particle segregation, acting as the main mechanism driving the good mixing of the binary particle species. The simulation results were in good agreement with the experimental data.
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2016 |
Azizian R, Doroodchi E, Moghtaderi B, 'Influence of Controlled Aggregation on Thermal Conductivity of Nanofluids', JOURNAL OF HEAT TRANSFER-TRANSACTIONS OF THE ASME, 138 (2016) [C1]
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2016 |
Cai J, Peng Z, Wu C, Zhao X, Yuan Z, Moghtaderi B, Doroodchi E, 'Numerical Study of the Orientation of Cylindrical Particles in a Circulating Fluidized Bed', INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH, 55 12806-12817 (2016) [C1]
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2016 |
Peng Z, Joshi JB, Moghtaderi B, Khan MS, Evans GM, Doroodchi E, 'Segregation and dispersion of binary solids in liquid fluidised beds: A CFD-DEM study', Chemical Engineering Science, 152 65-83 (2016) [C1] Liquid fluidised beds often operate with particles of different sizes and densities, encountering partial or complete segregation of solid particles at certain operating condition... [more] Liquid fluidised beds often operate with particles of different sizes and densities, encountering partial or complete segregation of solid particles at certain operating conditions. In this study, the segregation and dispersion of binary particle species of the same size but different densities in liquid fluidised beds have been investigated based on the analysis of computational fluid dynamics - discrete element method (CFD-DEM) simulation results.The vertical fluid drag force acting on the particles was found to be responsible for the particle segregation. The mechanisms governing the particle dispersion strongly depended upon the solid-liquid two-phase flow regime, which transited from pseudo-homogeneous to heterogeneous when the superficial liquid velocity reached a certain value. In the homogeneous or pseudo-homogeneous flow regime (Rep=40, ¿L, ave=0.74), particle collisions acted as the main mechanism that drove the dispersion of particles. However, after the system became heterogeneous, the magnitude of the vertical collision force decreased towards zero and correspondingly, the magnitude of the vertical fluid drag force was approaching that of the particle net weight force as the superficial liquid velocity increased. Therefore, in the heterogeneous flow regime (Rep>40, ¿L, ave>0.74), the local turbulence of the fluid flow and particle collisions (if there were any) were found to be the main mechanisms that drove the dispersion of particles in all directions. The dispersion coefficient of individual particles varied significantly throughout the system in the heterogeneous flow regime. The simulation results reasonably agreed with the experimental data and the prediction results by existing correlations.
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2016 |
Zhang Y, Doroodchi E, Moghtaderi B, Han X, Liu Y, 'Hydrogen Production from Ventilation Air Methane in a Dual-Loop Chemical Looping Process', ENERGY & FUELS, 30 4372-4380 (2016) [C1]
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2016 |
Khairul MA, Doroodchi E, Azizian R, Moghtaderi B, 'Experimental Study on Fundamental Mechanisms of Ferro-Fluidics for an Electromagnetic Energy Harvester', INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH, 55 12491-12501 (2016) [C1]
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2016 |
Yang N, Yu JL, Dou JX, Tahmasebi A, Song H, Moghtaderi B, et al., 'The effects of oxygen and metal oxide catalysts on the reduction reaction of NO with lignite char during combustion flue gas cleaning', Fuel Processing Technology, 152 102-107 (2016) [C1] The development of lignite-char-supported metal oxide catalyst for reduction of nitric oxide (NO) is investigated in this paper. The characteristics of NO reduction by copper and ... [more] The development of lignite-char-supported metal oxide catalyst for reduction of nitric oxide (NO) is investigated in this paper. The characteristics of NO reduction by copper and iron oxide catalysts supported on activated lignite chars (ALC) was studied using a fixed-bed reactor at 300 °C. The results showed that the impregnation of Cu on ALC resulted in higher catalytic reactivity during NO reduction compared with that of Fe. Chemisorption of O2 and NO on Cu/ALC catalyst was found to play an important role in denitrification. Fourier transform infrared spectroscopy (FTIR) and X-ray diffraction (XRD) analyses showed that chemically adsorbed oxygen facilitates the formation of C(O) complex and oxidation of Cu0 to Cu+ for Cu/ALC catalyst. The C(O) intermediates and C*production formed due to the fact that C/O2 reaction promoted the reduction of NO. It is suggested that the catalytic reaction of NO in this case comprised of C/O2 reaction, C(O)/NO reaction and formation of N2 and CO2. Cu seemed to have significantly promoted the C(O) formation and CO oxidation compared with Fe. The catalytic reactivity of Cu species for C(O) formation and CO oxidation followed the order of Cu0 > Cu+ > Cu2 +. Fe3O4 was believed to be the active phase in Fe catalyst. The oxygen and char-supported metal catalysts significantly promoted C/NO reaction, and therefore may lead to a lower operation temperature of NOx removal.
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2016 |
Zhou C, Remoroza AI, Shah K, Doroodchi E, Moghtaderi B, 'Experimental study of static and dynamic interactions between supercritical CO2/water and Australian granites', GEOTHERMICS, 64 246-261 (2016) [C1]
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2016 |
Dar T, Shah K, Moghtaderi B, Page AJ, 'Formation of persistent organic pollutants from 2,4,5-trichlorothiophenol combustion: a density functional theory investigation', Journal of Molecular Modeling, 22 (2016) [C1] Polychlorinated dibenzothiophene (PCDT) and polychlorinated thianthrene (PCTA) are sulfur analogues of dioxins, such as polychlorinated dibenzo-p-dioxins and polychlorinated diben... [more] Polychlorinated dibenzothiophene (PCDT) and polychlorinated thianthrene (PCTA) are sulfur analogues of dioxins, such as polychlorinated dibenzo-p-dioxins and polychlorinated dibenzofurans (PCDD/F). In this work, we present a detailed mechanistic and kinetic analysis of PCDT and PCTA formation from the combustion of 2,4,5-trichlorothiophenol. It is shown that the formation of these persistent organic pollutants is more favourable, both kinetically and thermodynamically, than their analogous dioxin counterparts. This is rationalised in terms of the different influences of the S¿H and O¿H moieties in the 2,4,5-trichlorothiophenol and 2,4,5-trichlorophenol precursors. Kinetic parameters also indicate that the yield of PCDT should exceed that of PCDD. Finally, we demonstrate here that the degree and pattern of chlorination on the 2,4,5-trichlorothiophenol precursor leads to subtle thermodynamic and kinetic changes to the PCDT/PCTA formation mechanisms. [Figure not available: see fulltext.]
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2016 |
Luo C, Zanganeh J, Moghtaderi B, 'A 3D numerical study on the effects of obstacles on flame propagation in a cylindrical explosion vessel connected to a vented tube', Journal of Loss Prevention in the Process Industries, 44 53-61 (2016) [C1] This article presents a numerical study of the explosive wave propagations from a 40¿cm long and 10.8¿cm diameter cylinder to smaller 1.7¿m and 2.6¿m long cylinders with 36¿mm dia... [more] This article presents a numerical study of the explosive wave propagations from a 40¿cm long and 10.8¿cm diameter cylinder to smaller 1.7¿m and 2.6¿m long cylinders with 36¿mm diameters. Initially, the 40¿cm long cylinder was filled with 4% propane-air mixtures and ignited with a 1¿kJ sparking energy until the maximum temperature near the ignition source reached 2400/3000¿K. In the study, a 3D numerical model was established by combining compressible four-step reduced propane oxidation reaction kinetics with the k-¿ shear-stress transport (SST) turbulent model. In order to resolve the thin detonation wave front, a dynamically refined mesh near the high pressure gradient was adopted. The pressure gradient profiles, velocity magnitude contours, temperature contours and compressible wave propagation speeds across the tubes were then predicted using this 3D model.
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2016 |
Gai S, Yu J, Yu H, Eagle J, Zhao H, Lucas J, et al., 'Process simulation of a near-zero-carbon-emission power plant using CO2 as the renewable energy storage medium', INTERNATIONAL JOURNAL OF GREENHOUSE GAS CONTROL, 47 240-249 (2016) [C1]
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2016 |
Albatayneh A, Alterman D, Page AW, Moghtaderi B, 'Warming issues associated with the long term simulation of housing using CFD analysis', Journal of Green Building, 11 59-74 (2016) [C1] The determination of internal building air temperature has an impact on the design and performance of a building in measuring thermal comfort and heating and cooling loads. There ... [more] The determination of internal building air temperature has an impact on the design and performance of a building in measuring thermal comfort and heating and cooling loads. There is software to assist with measuring internal building air temperature such as Autodesk CFD simulation. However, the use of Autodesk CFD simulation for the analysis appears to have an issue with simulations extending over a long term (i.e. months or years) as the internal air temperature in a building keeps rising with time. This paper addresses the challenges encountered using CFD simulation in the modelling of a building for long term performance. A new method to overcome the issue of the progressive rising of internal air temperature using two external air boundaries, one for the external volume (sky boundary) and the other surrounding the building, is suggested in the paper.
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2016 |
Kundu S, Zanganeh J, Moghtaderi B, 'A review on understanding explosions from methane-air mixture', Journal of Loss Prevention in the Process Industries, 40 507-523 (2016) [C1] This review examines existing knowledge on the genesis and flame acceleration of explosions from methane-air mixtures. Explosion phases including deflagration and detonation and t... [more] This review examines existing knowledge on the genesis and flame acceleration of explosions from methane-air mixtures. Explosion phases including deflagration and detonation and the transition from deflagration to detonation have been discussed. The influence of various obstacles and geometries on explosions in an underground mine and duct have been examined. The discussion, presented here, leads the readers to understand the considerations which must be accounted for in order to obviate and/or mitigate any accidental explosion originating from methane-air systems.
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2016 |
Peng Z, Moghtaderi B, Doroodchi E, 'A modified direct method for void fraction calculation in CFD-DEM simulations', Advanced Powder Technology, 27 19-32 (2016) [C1] The void fraction of computational cells in numerical simulations of particulate flows using computational fluid dynamics-discrete element method (CFD-DEM) is often directly (or c... [more] The void fraction of computational cells in numerical simulations of particulate flows using computational fluid dynamics-discrete element method (CFD-DEM) is often directly (or crudely) calculated assuming that the entire body of a particle lies in the cell at which the particle centroid resides. This direct method is most inexpensive but inaccurate and may lead to simulation instabilities. In this study, a modified version of the direct method has been proposed. In this method, referred to as the particle meshing method (PMM), the particle is meshed and the solid volume in a fluid cell is calculated by adding up the particle mesh volume with the basic working principle being the same as that of the direct method. As a result, the PMM inherits the simplicity and hence the computational advantage from the direct method, whilst allowing for duplicating the particle shape and accurate accounting of particle volume in each fluid cell. The numerical simulation characteristics of PMM including numerical stability, minimum particle grid number, prediction accuracy, and computational efficiency have been examined. The results showed that for a specific cell-to-particle size ratio, there was a minimum particle grid number required to reach the stable simulation. A formula of estimating the minimum particle grid number was derived and discussed. Typically, a particle grid number of about 5 times the minimum number was suggested to achieve the best computational efficiency, which was comparable or even higher than that of simulations using the analytical approach. PMM also exhibited the potential to be applied for complex computational domain geometries and irregular shaped particles.
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2016 |
Albatayneh A, Alterman D, Page A, Moghtaderi B, 'Assessment of the Thermal Performance of Complete Buildings Using Adaptive Thermal Comfort', URBAN PLANNING AND ARCHITECTURAL DESIGN FOR SUSTAINABLE DEVELOPMENT (UPADSD), 216 655-661 (2016) [C1]
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2016 |
Luo C, Zanganeh J, Moghtaderi B, 'A 3D numerical study of detonation wave propagation in various angled bending tubes', Fire Safety Journal, 86 53-64 (2016) [C1] This paper conducts a numerical study of detonation wave propagations in 30 m and 73 m long straight/varying angle bending detonation tubes with inner diameters of 0.5 m and 1.05 ... [more] This paper conducts a numerical study of detonation wave propagations in 30 m and 73 m long straight/varying angle bending detonation tubes with inner diameters of 0.5 m and 1.05 m, respectively, which are filled with varying stoichiometric methane-air mixtures. In the study a 3D numerical model was established by combining a compressible one-step global reaction hot model with the k-¿ shear-stress transport (SST) turbulent model. In order to resolve the thin detonation wave front, a dynamically refined mesh near the high pressure gradient is adopted. The initial conditions of the model are obtained from the 1D detonation model. The present model was first verified by comparing the numerical results against the published measurements. The pressure distributions and detonation wave speeds across the tubes and bends were then predicted by using this 3D model.
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2016 |
Ajrash MJ, Zanganeh J, Moghtaderi B, 'Effects of ignition energy on fire and explosion characteristics of dilute hybrid fuel in ventilation air methane', Journal of Loss Prevention in the Process Industries, 40 207-216 (2016) [C1] Deflagration explosions of coal dust clouds and flammable gases are a major safety concern in coal mining industry. Accidental fire and explosion caused by coal dust cloud can imp... [more] Deflagration explosions of coal dust clouds and flammable gases are a major safety concern in coal mining industry. Accidental fire and explosion caused by coal dust cloud can impose substantial losses and damages to people and properties in underground coal mines. Hybrid mixtures of methane and coal dust have the potential to reduce the minimum activation energy of a combustion reaction. In this study the Minimum Explosion Concentration (MEC), Over Pressure Rise (OPR), deflagration index for gas and dust hybrid mixtures (Kst) and explosive region of hybrid fuel mixtures present in Ventilation Air Methane (VAM) were investigated. Experiments were carried out according to the ASTM E1226-12 guideline utilising a 20 L spherical shape apparatus specifically designed for this purpose. Results: obtained from this study have shown that the presence of methane significantly affects explosion characteristics of coal dust clouds. Dilute concentrations of methane, 0.75-1.25%, resulted in coal dust clouds OPR increasing from 0.3 bar to 2.2 bar and boosting the Kst value from 10 bar m s-1 to 25 bar m s-1. The explosion characteristics were also affected by the ignitors' energy; for instance, for a coal dust cloud concentration of 50 g m-3 the OPR recorded was 0.09 bar when a 1 kJ chemical ignitor was used, while, 0.75 bar (OPR) was recorded when a 10 kJ chemical ignitor was used.For the first time, new explosion regions were identified for diluted methane-coal dust cloud mixtures when using 1, 5 and 10 kJ ignitors. Finally, the Le-Chatelier mixing rule was modified to predict the lower explosion limit of methane-coal dust cloud hybrid mixtures considering the energy of the ignitors.
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2015 |
Ahubelem N, Shah K, Moghtaderi B, Page AJ, 'Quantum Chemical Molecular Dynamics Simulations of 1,3-Dichloropropene Combustion.', J Phys Chem A, 119 9307-9316 (2015) [C1]
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2015 |
Ahubelem N, Shah K, Moghtaderi B, Altarawneh M, Dlugogorski BZ, Page AJ, 'Formation of chlorobenzenes by oxidative thermal decomposition of 1,3-dichloropropene', Combustion and Flame, (2015) [C1] We combine combustion experiments and density functional theory (DFT) calculations to investigate the formation of chlorobenzenes from oxidative thermal decomposition of 1,3-dichl... [more] We combine combustion experiments and density functional theory (DFT) calculations to investigate the formation of chlorobenzenes from oxidative thermal decomposition of 1,3-dichloropropene. Mono- to hexa-chlorobenzenes are observed between 800 and 1150. K, and the extent of chlorination was proportional to the combustion temperature. Higher chlorinated congeners of chlorobenzene (tetra-, penta-, hexa-chlorobenzene) are only observed in trace amounts between 950 and 1050. K. DFT calculations indicate that cyclisation of chlorinated hexatrienes proceeds via open-shell radical pathways. These species represent key components in the formation mechanism of chlorinated polyaromatic hydrocarbons. Results presented herein should provide better understanding of the evolution of soot from combustion/pyrolysis of short chlorinated alkenes.
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2015 |
Zhou C, Shah K, Doroodchi E, Moghtaderi B, 'Equilibrium thermodynamic analyses of methanol production via a novel Chemical Looping Carbon Arrestor process', Energy Conversion and Management, 96 392-402 (2015) [C1] Abstract Methanol economy is considered as an alternative to hydrogen economy due to the better handling and storage characteristics of methanol fuel than liquid hydrogen. This pa... [more] Abstract Methanol economy is considered as an alternative to hydrogen economy due to the better handling and storage characteristics of methanol fuel than liquid hydrogen. This paper is concerned about a comprehensive equilibrium thermodynamic analysis carried out on methanol production via an innovative Chemical Looping Carbon Arrestor/Reforming process being developed at the University of Newcastle in order to reduce both energy consumption and carbon emissions. The detailed simulation revealed thermodynamic limitations within the Chemical Looping Carbon Reforming process however on the other hand it also confirmed that the new concept is a low energy requirement and low emission option compared to other methanol production technologies. Specifically, the mass and energy balance study showed that the Chemical Looping Carbon Reforming process typically consumes approximately 0.76-0.77 mole methane, 0.25-0.27 mole carbon dioxide, 0.49-0.50 mole water, and 0.51 mole iron oxide (in a chemical looping manner) per mole of methanol production. Moreover, the energy efficiency of Chemical Looping Carbon Reforming process was found to be ~64-70% and its emission profile was found as low as 0.14 mole carbon dioxide per mole of methanol, which is about 82-88% less than the conventional methanol production process and well below the emission levels of other emerging methanol production technologies.
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2015 |
Cummings J, Shah K, Atkin R, Moghtaderi B, 'Physicochemical interactions of ionic liquids with coal; The viability of ionic liquids for pre-treatments in coal liquefaction', Fuel, 143 244-252 (2015) [C1] Three Australian sub-bituminous coals were treated with three different ionic liquids (ILs) at a temperature of 100 °C. The thermal behaviour of these treated coals were compared ... [more] Three Australian sub-bituminous coals were treated with three different ionic liquids (ILs) at a temperature of 100 °C. The thermal behaviour of these treated coals were compared against raw coals via pyrolysis experiments in a Thermogravimetric Analyser. Morphological comparisons were also made via Scanning Electron Microscopy. Among the studied ILs, 1-butyl-3-methylimidazolium chloride [Bmim][Cl] was found to perform the most consistently in being able to alter the thermal and morphological properties of most of the coals used. It is posited that this may be due to the large difference in charge density between the delocalised charge of the large bmim cation and the chloride anion which allows this IL to disrupt the cross linked network of coal. It was also found that the interactions of the ionic liquids are coal specific, for instance none of the ionic liquids were able to change the thermal properties of coal A. Moreover, the results indicated that among the studied coals, coal R showed the highest mass loss during pyrolysis in TGA and coal C showed the highest amount of swelling and fragmentation in SEM images. The results displayed in this study indicate that the potential for ionic liquids to be used as pre-treatments in coal liquefaction is promising. Crown
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2015 |
Shah K, Zhou C, Song H, Doroodchi E, Moghtaderi B, 'A novel hybrid chemical-looping oxy combustor process for the combustion of solid and gaseous fuels: Thermodynamic analysis', Energy and Fuels, 29 602-617 (2015) [C1] The larger reactor volume, additional oxygen polishing unit, and carbon stripper for the separation of oxygen carriers and ash in the chemical looping combustion (CLC) and/or chem... [more] The larger reactor volume, additional oxygen polishing unit, and carbon stripper for the separation of oxygen carriers and ash in the chemical looping combustion (CLC) and/or chemical looping oxygen uncoupling (CLOU) processes for solid fuels are anticipated not only to incur operational complexity but also to increase the capital and operating costs. As an alternative, this paper proposes a novel hybrid process, called "Chemical Looping Oxy Combustor (CLOC)". This novel process provides an integration of chemical looping air separation (CLAS) with fluidized bed oxy-fuel combustion and is expected to eliminate the need for an additional oxygen polishing unit and carbon stripper. It can be retrofitted to any existing coal circulating fluidized bed (CFB) at low cost. The other advantages of CLOC includes less solid handling issues, flexibility in handling low-grade coal with high moisture, no/less contamination of oxygen carriers, no/less slip of CO2/SOx in an air reactor, low energy penalty, etc. Also, in the CLOC process, coal combustion will occur in a separate fluidized bed combustor with relatively faster kinetics, because of the availability of high oxygen concentration (i.e., ~25-28 vol-"%), which eliminates the need for a larger fuel reactor volume. In the current paper, thermodynamic simulations of CLOC process using Cu-, Mn-, and Co-based metal oxide oxygen carriers were performed. Their performances were also compared against the conventional air-firing and oxy-firing technologies, e.g., oxy-fuel combustion integrated with cryogenic air separation unit (CASU) and CLOU. It was identified that the CLOC process needs external heat for reduction reactor provided by either direct or indirect methane combustion. Moreover, a maximum plant thermal efficiency was achieved for CLOC using Cu-based oxygen carrier. The energy penalty of the CLOC process, compared with the air-firing base case, was found to be ~2%-3%, which is ~4-5 times smaller than those of the CASU cases and only half of that of the CLOU process, indicating that CLOC offers a promising option for the combustion of solid fuels.
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2015 |
Zhang Y, Doroodchi E, Moghtaderi B, 'Comprehensive study of Fe An experimental study was conducted to identify the most suitable alumina-supported iron-based oxygen carrier for the abatement of ultralow concentration methane using a chemical ... [more] An experimental study was conducted to identify the most suitable alumina-supported iron-based oxygen carrier for the abatement of ultralow concentration methane using a chemical looping approach. This was done by evaluating the performance characteristics such as reactivity, cyclic stability, and gas conversion. The experiments were carried out in a thermogravimetric analyzer and a fixed bed reactor setup under the desired conditions. Thermodynamics analysis was carried out using the commercially available software ASPENPLUS. The analysis suggested that the favorable iron-based oxygen carriers were those with the weight content of Fe2O3 less than 50 wt %. Three Fe2O3/Al2O3 samples were therefore prepared with the metal oxide contents in the range of 10-45 wt %, i.e., Fe10Al, Fe25Al, and Fe45Al. The thermogravimetric analysis experimental results showed that the reduction reactivity and stability were improved with the addition of support material compared with unsupported Fe2O3. Moreover, the reduction reactivity varied with the solid conversion range and the weight content of the parent material. For full reduction of Fe2O3 to Fe3O4, the sample Fe10Al showed the highest reduction reactivity. However, in terms of the rate of oxygen transport (which considers the combined effects of the oxygen transfer capacity and reactivity), the highest value was achieved by the Fe45Al sample. The gas conversion of CH4 to CO2 was also quite dependent on the weight content of Fe2O3. Essentially, Fe45Al delivered the longest duration on high-level conversion (i.e., complete conversion of CH4 to CO2). In summary, Fe45Al was found to be the most suitable oxygen carrier candidate in this application. The effect of operational parameters was further examined with various reaction temperatures (873-1073 K), methane concentrations (0.1-1.5 vol %), and CO2 compositions (0-50 vol %).
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2015 |
Zhou C, Shah K, Moghtaderi B, 'Techno-economic assessment of integrated chemical looping air separation for oxy-fuel combustion: An Australian case study', Energy and Fuels, 29 2074-2088 (2015) [C1] A techno-economic analysis was carried out to assess the oxy-fuel conversion of eight major coal-fired power plants in the state of NSW, Australia. For this purpose, several alter... [more] A techno-economic analysis was carried out to assess the oxy-fuel conversion of eight major coal-fired power plants in the state of NSW, Australia. For this purpose, several alternative retrofit configurations, differing only in the air separation unit (ASU) but otherwise identical, were considered. More specifically, three types of oxygen plants were studied: a cryogenic-based air separation unit and integrated chemical looping air separation units using steam (ICLAS[S]) and recycled flue gas (ICLAS[FG]) as the reduction medium. The main objective of the techno-economic analysis was to determine if the economic viability of oxy-fuel operations could be enhanced by incorporating ICLAS technology. The results show that the normalized oxygen demand for the NSW fleet of coal-fired power plants was about 450-550 m3/MWh, with Bayswater having the lowest normalized oxygen demand and Munmorah having the highest one. Moreover, it was found that by replacing a cryogenic-based ASU with an ICLAS unit, the average reduction in the ASU power demand was up to 47% and 76%, respectively, for ICLAS[S] and ICLAS[FG]. Similarly, the average thermal efficiency penalty associated with the cryogenic and the ICLAS[S] and ICLAS[FG] units was found to be about 9.5%, 7.5%, and 5%, respectively, indicating that the ICLAS[FG] unit is the most energy efficient option for oxy-fuel plants. Economic analyses suggest that a retrofit cost reduction of about 32% can be achieved by incorporating an ICLAS[FG] unit. On average, the levelized cost of electricity associated with the cryogenic and the ICLAS[S] and ICLAS[FG] units for the NSW fleet of coal-fired power plants was found to be about $118/MWh, $105/MWh, and $95/MWh, respectively.
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2015 |
Moffiet T, Alterman D, Hands S, Colyvas K, Page A, Moghtaderi B, 'A statistical study on the combined effects of wall thermal mass and thermal resistance on internal air temperatures', Journal of Building Physics, 38 419-443 (2015) [C1] Statistical analyses are important for real-world validation of theoretical model predictions. In this article, a statistical analysis of real data shows empirically how thermal r... [more] Statistical analyses are important for real-world validation of theoretical model predictions. In this article, a statistical analysis of real data shows empirically how thermal resistance, thermal mass, building design, season and external air temperature collectively affect indoor air temperature. A simple, four-point, diurnal, temperature-by-time profile is used to summarise daily thermal performance and is used as the response variable for the analysis of performance. The findings from the statistical analysis imply that, at least for moderate climates, the best performing construction/design will be one in which insulation and thermal mass arrangements can be dynamically altered to suit weather and season.
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2015 |
Alterman D, Page AW, Moghtaderi B, Zhang C, Moffiet T, 'The influence of thermal resistance and thermal mass on the seasonal performance of walling systems in Australia', Journal of Green Building, 10 107-126 (2015) [C1] This paper describes an experimental investigation of the thermal performance of four Australian domestic walling systems (cavity brick, insulated cavity brick, insulated brick ve... [more] This paper describes an experimental investigation of the thermal performance of four Australian domestic walling systems (cavity brick, insulated cavity brick, insulated brick veneer and insulated reverse brick veneer) having various combinations of thermal insulation and of thermal mass location within the wall. This experimental analysis extends further the previous studies of the benefits of thermal mass on the overall thermal performance of building enclosures (Gregory et al. 2008, Luo at al. 2008, Alashaary et al. 2009). The comparison is based on the time required to maintain thermal comfort for free-floating internal conditions. The results clearly show that internal comfort levels are influenced by both the thermal resistance of the walls as well as the extent and location of the thermal mass, with neither parameter being the sole predictor. The best thermal performance is therefore obtained by an appropriate combination of thermal mass and resistance, rather than focussing on the overall wall thermal resistance (R-value) alone. A new approach of density temperature plots for comparison of temperature variation is also used in the assessment of module thermal performance.
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2015 |
Shah K, Moghtaderi B, Doroodchi E, Sandford J, 'A feasibility study on a novel stone dust looping process for abatement of ventilation air methane', Fuel Processing Technology, 140 285-296 (2015) [C1] This paper describes the development of a novel stone dust looping process that relates to the removal of ventilation air methane using stone dust. The working principle behind th... [more] This paper describes the development of a novel stone dust looping process that relates to the removal of ventilation air methane using stone dust. The working principle behind the stone dust looping process is incredibly simple which involves the catalytic oxidation of methane followed by carbonation and calcination reactions. In the current work, laboratory scale fluidized bed experiments and process simulations were conducted to evaluate the feasibility of the stone dust looping process. The experimental work concluded that oxidation of ventilation air methane in the stone dust looping process can be successfully achieved at temperatures between 500 and 650 °C. The experimental results indicated that oxidation of methane was found to increase at higher temperatures while carbon dioxide capture efficiency showed a declining trend with increasing temperature. Furthermore, higher methane conversion and optimum (thermodynamic) carbon dioxide capture efficiency were observed for lower ventilation air methane flow rates and higher bed inventory. The concentration of methane in ventilation air methane and stone dust particle size did not have a significant effect on methane conversion or carbon dioxide capture. Also, comparison with synthetically prepared CuO and Fe<inf>2</inf>O<inf>3</inf> catalysts has been made with CaO for VAM oxidation. CaO was found to be comparable to Fe<inf>2</inf>O<inf>3</inf> and superior to CuO. From the process simulations, it was concluded that thermal energy generation in the carbonator was increased with higher methane and carbon dioxide concentrations. However, at the same time for higher methane and carbon dioxide concentrations, a greater CaO flux was required in the carbonator and hence a larger amount of goaf gas was required for the calcination reaction. The higher thermal energy generation in the carbonator was expected to improve the autothermicity of the stone dust looping process at concentrations of methane in the ventilation stream < 0.2 vol.% (thermodynamic limit).
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2015 |
Ramezani M, Shah K, Doroodchi E, Moghtaderi B, 'Application of a novel calcium looping process for production of heat and carbon dioxide enrichment of greenhouses', Energy Conversion and Management, 103 129-138 (2015) [C1] Abstract Greenhouses typically employ conventional burner systems to suffice heat and carbon dioxide required for plant growth. The energy requirement and carbon dioxide emissions... [more] Abstract Greenhouses typically employ conventional burner systems to suffice heat and carbon dioxide required for plant growth. The energy requirement and carbon dioxide emissions from fossil fuel burner are generally high. As an alternative, this paper describes a novel greenhouse calcium looping process which is expected to decrease the energy requirements and associated carbon dioxide emissions. The conceptual design of greenhouse calcium looping process is carried out in the ASPEN Plus v 7.3 simulator. In a greenhouse calcium looping process, the calcination reaction is considered to take place during day time in order to provide the required optimum carbon dioxide between 1000 and 2000 ppm, while the carbonation reaction is occurred during night time to provide required heat. The process simulations carried out in ASPEN indicates that greenhouse calcium looping process theoretically attributes to zero emission of carbon dioxide. Moreover, in a scenario modelling study compared to the conventional natural gas burner system, the heat duty requirements in the greenhouse calcium looping process were found to reduce by as high as 72%.
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2015 |
Alterman D, Page AW, Moffiet T, Moghtaderi B, 'A Measure for the Dynamic Thermal Performance of Walling Systems Incorporating the Combined Effect of Thermal Mass and Thermal Resistance', Masonry International: Journal of the British Masonry Society, 28 11-18 (2015) [C1]
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2015 |
Zhang Y, Doroodchi E, Moghtaderi B, 'Reduction kinetics of Fe Fe2O3/Al2O3 is found to be a suitable oxygen carrier candidate for the chemical looping combustion with ultralow methane concentration in a previous study by our team. In order to... [more] Fe2O3/Al2O3 is found to be a suitable oxygen carrier candidate for the chemical looping combustion with ultralow methane concentration in a previous study by our team. In order to facilitate the fundamental reactor design and understand the energy consumption, the reduction kinetics mechanism of Fe2O3 (hematite) with 0.5 vol % CH4 was determined and the kinetic parameters were estimated based on the thermogravimetric analysis. Two oxygen carriers (i.e., Fe25Al and Fe45Al) were prepared and used in the TGA experiment. It was observed that the reduction of Fe2O3 was a two-steps process. Initially, Fe2O3 is transformed into Fe3O4 (magnetite) at a fast reaction rate and followed by a slow step corresponding to the reduction from Fe3O4 to FeAl2O4. A topochemical approach associated with Hancock and Sharp's method was therefore applied to determine the most suitable kinetic model for the reduction process. It was found that the initial fast step can be described by the Avrami-Erofe'ev phase change model, the A2 model for low conversion, and the A3 model for high conversion, whereas the reaction for the second step was in diffusion control. It also can be concluded that within the Fe2O3 content of 25-45 wt %, there is no difference on the reduction kinetic mechanism and similar activation energy was obtained, which can be comparable with the findings in the literature.
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2015 |
Peng Z, Doroodchi E, Alghamdi YA, Shah K, Luo C, Moghtaderi B, 'CFD-DEM simulation of solid circulation rate in the cold flow model of chemical looping systems', Chemical Engineering Research and Design, 95 262-280 (2015) [C1] In a chemical looping combustor (CLC) system, the solid circulation rate (SCR) is a key parameter that determines the design, operating conditions and the overall efficiency of th... [more] In a chemical looping combustor (CLC) system, the solid circulation rate (SCR) is a key parameter that determines the design, operating conditions and the overall efficiency of the system. In the present work, the gas-solid flow of a CLC cold flow model (10kWth) has been simulated by the computational fluid dynamics-discrete element method (CFD-DEM). The results showed that the SCR at different locations of the system fluctuates with time with different amplitude, and the variation of SCR is periodically stable. The turbulent gas-solid flow regime in the air reactor was found to be the main mechanism driving the fluctuation of SCR and determined the fluctuation frequency and amplitude. The SCR increased with the flow rates of air/fuel reactors and loop seals, and the total solid inventory. Changes in operating conditions directly induced the change in the mass of solids that were entrained into the riser from the air reactor and how fast the solids were transported therein. A correlation was subsequently proposed to describe the SCR as a function of solid hold-up and gas flow velocity in the riser. The particle residence time decreased in a power law as the SCR increased. Reasonable agreements were obtained between simulations and experiments in terms of solid distribution, gas-solid flow patterns, pressure drop profiles and SCR.
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2015 |
Alterman D, Page A, Moghtaderi B, Zhang C, 'Contribution of thermal resistance and thermal mass to the energy demand of walling systems / Beitrag des Wärmedurchlasswiderstandes und der thermischen Masse zum Energiebedarf von Wandsystemen', Mauerwerk, 19 64-73 (2015) [C1]
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2015 |
Albatayneh A, Alterman D, Page A, Moghtaderi B, 'The Significance of Time Step Size in Simulating the Thermal Performance of Buildings', Advances in Research, 5 1-12 [C1]
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2015 |
Ahubelem N, Shah K, Moghtaderi B, Page AJ, 'Formation of benzofuran and chlorobenzofuran from 1,3-dichloropropene: A quantum chemical investigation', International Journal of Quantum Chemistry, 115 1739-1745 (2015) [C1] We present a quantum chemical investigation of benzofuran and cholorobenzofuran formation mechanisms during the combustion of 1,3-dichloropropene. Density functional theory and Ga... [more] We present a quantum chemical investigation of benzofuran and cholorobenzofuran formation mechanisms during the combustion of 1,3-dichloropropene. Density functional theory and Gaussian-n thermochemical methods are used to propose detailed mechanistic reaction pathways. These calculations indicate that oxidation of phenylvinyl radical intermediates and subsequent ring closure are key mechanistic pathways in the formation of benzofuran and chlorobenzofuran. Thermochemical and kinetic parameters presented herein will assist in further elucidation of dioxin formation mechanisms from thermolyses of hydrocarbon moieties.
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2015 |
Cummings J, Kundu S, Tremain P, Moghtaderi B, Atkin R, Shah K, 'Investigations into Physicochemical Changes in Thermal Coals during Low-Temperature Ionic Liquid Treatment', Energy and Fuels, 29 7080-7088 (2015) [C1] Two Australian thermal coals were treated with four different ionic liquids (ILs) at temperatures as low as 100 °C. The ILs used were 1-butylpyridinium chloride ([Bpyd][Cl]), 1-et... [more] Two Australian thermal coals were treated with four different ionic liquids (ILs) at temperatures as low as 100 °C. The ILs used were 1-butylpyridinium chloride ([Bpyd][Cl]), 1-ethyl-3-methylimidazolium dicyanamide ([Emim][DCM]), 1-butyl-3-methylimidazolium chloride ([Bmim][Cl]), and 1-butyl-3-methylimidazolium tricyanomethanide ([Bmim][TCM]). Visual comparisons were made between the raw and IL-treated coals via optical microscopy. Changes in thermal behavior of these treated coals were compared against raw coals via pyrolysis experiments in a thermogravimetric analyzer (TGA). Changes in functional group composition in the treated coals were probed via Fourier transform infrared (FTIR) spectroscopy. The recovered ILs were also analyzed via FTIR and nuclear magnetic resonance (NMR) spectroscopies to observe any changes after recovery. Low-temperature IL treatment of each of the coals resulted in fragmentation and fracturing, reducing the average particle size. An increase in mass loss in the treated coals was also observed when compared to each raw coal, indicating an increase in lower molecular weight fragments after treatment. This was corroborated by a large increase in aliphatic hydrocarbons being observed in the treated coals, along with a decrease in oxygenated functional groups and mineral matter in one coal. The recovered ILs were shown to be unchanged by this treatment process, indicating their potential recyclability. These results indicate the potential for ILs to be implemented as solvent treatments for coal conversion processes.
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2015 |
Peng Z, Doroodchi E, Sathe M, Joshi JB, Evans GM, Moghtaderi B, 'A method for calculating the surface area of numerically simulated aggregates', Advanced Powder Technology, 26 56-65 (2015) [C1] The success of many industrial processes largely depends on the structural characteristics of aggregates. In intensive aerobic digestion process for wastewater treatment applicati... [more] The success of many industrial processes largely depends on the structural characteristics of aggregates. In intensive aerobic digestion process for wastewater treatment applications, the structural characteristics namely aggregate shape, size and therefore the aggregate surface area strongly influence the transfer of dissolved oxygen from the aeration process to aggregates of harmful contaminants/microorganisms. The aim of this study was to apply Discrete Element Modelling (DEM) techniques to the aggregation of suspended particles (microorganisms) to quantify the available surface area for convection and diffusion as a function of particles number concentration and surface charge. The simulation inputs included particle and fluid characteristics such as particle size and density, solid concentration, suspension pH and ionic strength. A post processing method based on the Go-chess concept was developed to quantify the surface area of aggregate structure. The simulation results showed that whilst an increase in connection points increases the total surface area of the aggregate, this does not necessarily translate into an increase in the surface area available for oxygen transfer as combinations of open and close pores are formed. Aggregate surface area was directly determined by aggregate structural characteristics, and increased rapidly when the coordination number was below 3.5 and the fractal dimension was less than 1.5. A correlation for prediction of aggregate external surface area was also proposed as a function of aggregate structural characteristics in terms of fractal dimension and coordination number.
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2015 |
Alghamdi Y, Peng Z, Shah K, Moghtaderi B, Doroodchi E, 'Predicting the solid circulation rate in chemical looping combustion systems using pressure drop measurements', Powder Technology, 286 572-581 (2015) [C1] In chemical looping combustion systems, accurate measurement of the solid circulation rate (SCR) is crucial for optimising the system performance. Conventionally, the SCR is predi... [more] In chemical looping combustion systems, accurate measurement of the solid circulation rate (SCR) is crucial for optimising the system performance. Conventionally, the SCR is predicted using the riser total pressure drop leading to an overestimation of up to 70%. In this work, a model has been proposed for the SCR prediction using the pressure drop at the top section of the riser. The height of this top section was determined by the riser gas-solid flow characteristics, namely, the axial solid holdup profile and lateral solid flux profile. A kinematic model was developed to predict the axial solid holdup profile and the reduced solid flux model developed by Rhodes et al. (1992) was employed to predict the mass fraction of upwards flowing solids. The prediction results of the proposed model were validated against the experimental data obtained in this work and those reported in the literature, where the prediction accuracy of SCR was significantly improved (by up to 60%) with a deviation of around 15%.
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2014 |
Peng Z, Doroodchi E, Luo C, Moghtaderi B, 'Influence of void fraction calculation on fidelity of CFD-DEM simulation of gas-solid bubbling fluidized beds', AIChE Journal, (2014) [C1] The correct calculation of cell void fraction is pivotal in accurate simulation of two-phase flows using a computational fluid dynamics-discrete element method (CFD-DEM) approach.... [more] The correct calculation of cell void fraction is pivotal in accurate simulation of two-phase flows using a computational fluid dynamics-discrete element method (CFD-DEM) approach. Two classical approaches for void fraction calculations (i.e., particle centroid method or PCM and analytical approach) were examined, and the accuracy of these methodologies in predicting the particle-fluid flow characteristics of bubbling fluidized beds was investigated. It was found that there is a critical cell size (3.82 particle diameters) beyond which the PCM can achieve the same numerical stability and prediction accuracy as those of the analytical approach. There is also a critical cell size (1/19.3 domain size) below which meso-scale flow structures are resolved. Moreover, a lower limit of cell size (1.63 particle diameters) was identified to satisfy the assumptions of CFD-DEM governing equations. A reference map for selecting the ideal computational cell size and the suitable approach for void fraction calculation was subsequently developed. © 2014 American Institute of Chemical Engineers.
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2014 |
Peng Z, Ghatage SV, Doroodchi E, Joshi JB, Evans GM, Moghtaderi B, 'Forces acting on a single introduced particle in a solid-liquid fluidised bed', Chemical Engineering Science, 116 49-70 (2014) [C1] In a liquid fluidised bed system, the motion of each phase is governed by fluid-particle and particle-particle interactions. The particle-particle collisions can significantly aff... [more] In a liquid fluidised bed system, the motion of each phase is governed by fluid-particle and particle-particle interactions. The particle-particle collisions can significantly affect the motion of individual particles and hence the solid-liquid two phase flow characteristics. In the current work, computational fluid dynamics-discrete element method (CFD-DEM) simulations of a dense foreign particle introduced in a monodispersed solid-liquid fluidised bed (SLFB) have been carried out. The fluidisation hydrodynamics of SLFB, settling behaviour of the foreign particle, fluid-particle interactions, and particle-particle collision behaviour have been investigated. Experiments including particle classification velocity measurements and fluid turbulence characterisation by particle image velocimetry (PIV) were conducted for the validation of prediction results. Compared to those predicted by empirical correlations, the particle classification velocity predicted by CFD-DEM provided the best agreement with the experimental data (less than 10% deviation). The particle collision frequency increased monotonically with the solid fraction. The dimensionless collision frequency obtained by CFD-DEM excellently fit the data line predicted by the kinetic theory for granular flow (KTGF). The particle collision frequency increased with the particle size ratio (dP2/dP1) and became independent of the foreign particle size for high solid fractions when the fluidised particle size was kept constant. The magnitude of collision force was 10-50 times greater than that of gravitational force and maximally 9 times greater than that of drag force. A correlation describing the collision force as a function of bed voidage was developed for Stp>65 and dP2/dP1=2. A maximum deviation of less than 20% was obtained when the correlation was used for the prediction of particle collision force. © 2014 Elsevier Ltd.
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2014 |
Shah K, Atkin R, Stanger R, Wall T, Moghtaderi B, 'Interactions between vitrinite and inertinite-rich coals and the ionic liquid - [bmim][Cl]', Fuel, 119 214-218 (2014) [C1] The interactions between vitrinite and inertinite-rich coals and the ionic liquid butylimidazolium chloride ([bmim][Cl]) heated to 100 C have been characterised. Differences in th... [more] The interactions between vitrinite and inertinite-rich coals and the ionic liquid butylimidazolium chloride ([bmim][Cl]) heated to 100 C have been characterised. Differences in the interactions of coal macerals and ionic liquids have been identified. [bmim][Cl] is able to dissolve 22 wt% of a high-vitrinite coal fraction compared to 14 wt% of a high-inertinite coal fraction. The vitrinite-rich coal fraction tends to swell to a greater extent compared to the inertinite-rich coal fraction, which was fractured and fragmented rather than swelled. © 2013 Published by Elsevier Ltd. All rights reserved.
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2014 |
Liu D, Yu Y, Hayashi JI, Moghtaderi B, Wu H, 'Contribution of dehydration and depolymerization reactions during the fast pyrolysis of various salt-loaded celluloses at low temperatures', Fuel, 136 62-68 (2014) [C1] The loaded salts (NaCl, KCl, MgCl2, and CaCl2) have significantly different influence on the contribution of dehydration and depolymerization reactions to the decomposition of sug... [more] The loaded salts (NaCl, KCl, MgCl2, and CaCl2) have significantly different influence on the contribution of dehydration and depolymerization reactions to the decomposition of sugar structures during cellulose fast pyrolysis at 325 °C. The structures of salt-loaded celluloses already become cross-linked during heating-up period, largely due to the enhanced dehydration reactions catalyzed by inorganic species. As stronger Lewis acids, the alkaline earth metal ions (Mg2+ and Ca2+) are more effective than the alkali metal ions (Na+ and K+) to catalyze the dehydration reactions of sugar structures, leading to the formation of more cross-linked cellulose for the alkaline earth metal chloride-loaded celluloses. As a result, the majority of Mg and Ca are transformed into water-insoluble forms during the heating-up period, largely reducing the catalytic effects of these species on the dehydration of sugar structures during the subsequent isothermal pyrolysis. Rather, the dehydration of non-sugar structures is enhanced because the catalytic species are already bonded with non-sugar structures. In contrast, the dehydration of sugar structures during the heating-up period is less significant for the NaCl-loaded and KCl-loaded celluloses. The majority of Na and K are water-soluble after the heating-up period so that the dehydration of sugar structures is further enhanced during isothermal pyrolysis. The loaded salts have less influence on the depolymerization reactions. The contribution of depolymerization reactions to sugar conversion is relatively small during the heating-up stage, but increases substantially during isothermal pyrolysis. © 2014 Elsevier Ltd. All rights reserved.
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2014 |
Azizian R, Doroodchi E, McKrell T, Buongiorno J, Hu LW, Moghtaderi B, 'Effect of magnetic field on laminar convective heat transfer of magnetite nanofluids', INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER, 68 94-109 (2014) [C1]
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2014 |
Zhou C, Doroodchi E, Moghtaderi B, 'Assessment of geothermal assisted coal-fired power generation using an Australian case study', ENERGY CONVERSION AND MANAGEMENT, 82 283-300 (2014) [C1]
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2014 |
Zhang Y, Doroodchi E, Moghtaderi B, 'Chemical looping combustion of ultra low concentration of methane with Fe2O3/Al2O3 and CuO/SiO2', APPLIED ENERGY, 113 1916-1923 (2014) [C1]
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2014 |
Zanganeh J, Moghtaderi B, 'Investigation of flame propagation over an inclined fuel wetted porous bed', Fire Safety Journal, 67 113-120 (2014) [C1] This experimental study was conducted to investigate the rate of flame spread over an inclined porous solid (sand) wetted with finite quantities of fuel (iso-propanol). The study ... [more] This experimental study was conducted to investigate the rate of flame spread over an inclined porous solid (sand) wetted with finite quantities of fuel (iso-propanol). The study comprised experiments that were conducted over 15° and 30° inclined beds with depths ranging from 13.3 mm to 39.9 mm and consisting of average sand particle diameters ranging from 0.5 mm to 5 mm under quiescent, assisted and opposed airflow conditions. Analysis of the resulting data indicate that the rate of flame spread is significantly decreased by increasing the bed inclination angle or the airflow velocity and is applicable for both assisted and opposed directions. Furthermore, the rate of flame spread is decreased to the minimum value and actually ceased halfway along the bed with a 30° inclination angle. This behaviour was observed mainly for beds containing coarse sand particles. The rate of flame spread was higher for thinner beds rather coarse beds under any given airflow conditions. Finally, the rate of flame spread in upward direction was relatively quicker in comparison with downward direction counterpart. © 2014 Elsevier Ltd. All rights reserved.
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2014 |
Song H, Shah K, Doroodchi E, Moghtaderi B, 'Development of a Cu-Mg-Based Oxygen Carrier with SiO2 as a Support for Chemical Looping Air Separation', ENERGY & FUELS, 28 163-172 (2014) [C1]
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2014 |
Song H, Shah K, Doroodchi E, Wall T, Moghtaderi B, 'Analysis on Chemical Reaction Kinetics of CuO/SiO2 Oxygen Carriers for Chemical Looping Air Separation', ENERGY & FUELS, 28 173-182 (2014) [C1]
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2014 |
Tremain P, Zanganeh J, Hugo L, Curry S, Moghtaderi B, 'Characterization of "Chailings": A Char Created from Coal Tailings', ENERGY & FUELS, 28 7609-7615 (2014) [C1]
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2014 |
Song H, Shah K, Doroodchi E, Wall T, Moghtaderi B, 'Reactivity of Al The chemical looping air separation (CLAS) is a novel method for producing high-purity oxygen, which can be effectively integrated to oxy-fuel power plants. CuO/Cu2O, Mn2O3/Mn3O 4... [more] The chemical looping air separation (CLAS) is a novel method for producing high-purity oxygen, which can be effectively integrated to oxy-fuel power plants. CuO/Cu2O, Mn2O3/Mn3O 4, and Co3O4/CoO have been found to be the most thermodynamically suitable oxidation pairs for the CLAS process. In the current study, the reactivity and stability of these metal oxides were analyzed further. A total of six different oxygen carrier samples were prepared by the dry impregnation method on SiO2 and Al2O3 supports. Their redox behavior has been investigated in a thermogravimetric analyzer (TGA) at four different temperatures, i.e., 800, 850, 900, and 950 C, where the temperature-programmed oxygen release and oxidation were applied for 5 continuous cycles using nitrogen and air, respectively. The results indicate that, although relatively all oxygen carriers exhibited good reactivity, CuO/Cu2O with SiO2 and Co3O4/CoO with Al2O3 were found to be most stable. Furthermore, oxygen transport capacity (OTC) (%) and rate of oxygen transport (ROT) (% min-1) were calculated. It was found that Cu oxide with SiO 2 has the highest OTC of 4.77% as well as the highest ROT of 5.1 and 10.9% min-1 for oxygen release and oxidation, respectively, at 950 C. The CuO/SiO2 oxygen carrier also exhibited better stability for the 41 continuous cycle test, with only 10.3% loss in OTC compared to 22.3% for Co3O4/Al2O3. The grain size growth was found to be the key cause in the loss of OTC. The oxygen concentration in the outlet stream for the CuO/SiO2 oxygen carrier was measured in packed-bed experiments at different temperatures. It was observed that the oxygen concentration at the outlet of the reactor was consistent with the equilibrium values at studied temperatures. © 2014 American Chemical Society.
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2014 |
Yin F, Yu J, Dou J, Gupta S, Moghtaderi B, Lucas J, 'Sulfidation of iron-based sorbents supported on activated chars during the desulfurization of coke oven gases: Effects of Mo and Ce addition', Energy and Fuels, 28 2481-2489 (2014) [C1] Coke oven gas cleaning is an important issue in China, where it can be a source of liquefied natural gas (LNG) through the methanation process. In this study, char-supported sorbe... [more] Coke oven gas cleaning is an important issue in China, where it can be a source of liquefied natural gas (LNG) through the methanation process. In this study, char-supported sorbents were prepared by loading iron, cerium, and molybdenum into a Chinese lignite through co-precipitation, and the sorbents were used for dry desulfurization of coke oven gases. Desulfurization efficiency of the sorbents was examined using a fixed-bed reactor in a temperature range of 473-673 K using a simulated coke oven gas. A gas chromatograph equipped with both a flame photometric detector (FPD) and a thermal conductivity detector (TCD) was used to analyze gas composition, while X-ray diffraction and scanning electron microscopy were used to examine chemical phases and the dispersion pattern of the active constitutes of the sorbents. The experimental results showed that the highest desulfurization efficiency and sulfur capacity appeared at 673 K. The reactivity of the nanosized active components in the char increased with increasing the desulfurization temperature in the temperature range of 473-673 K. In the case of Fe-Mo-impregnated sorbents, Fe and Mo combined together to form complex Fe-Mo oxide phases. The introduction of Mo in the sorbent is found to greatly increase the sulfur capacity and desulfurization efficiency of the Fe sorbent supported on activated chars. The addition of Ce leads to noticeable improvement of the performance of Fe sorbent during sulfidation. The mechanisms and factors influencing the sulfidation reactions have also been discussed. © 2014 American Chemical Society.
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2014 |
Zhang Y, Moghtaderi B, Doroodchi E, 'Utilization of ventilation air methane as an oxidizing agent in chemical looping combustion', Energy Conversion and Management, (2014) [C1] Release of fugitive methane (CH) emissions from ventilation air in coal mines is a major source of greenhouse gas (GHG) emissions. Approximately 64% of methane emissions in coal m... [more] Release of fugitive methane (CH) emissions from ventilation air in coal mines is a major source of greenhouse gas (GHG) emissions. Approximately 64% of methane emissions in coal mine operations are the result of VAM (i.e. ventilation air methane) which is difficult for use as a source of energy. A novel ancillary utilization of VAM was thereby proposed. In this proposal, the VAM was utilized instead of air as a feedstock to a chemical looping combustion (CLC) process of coal. In this case, FeO/FeO particles were shuttled between two interconnected reactors for combustion of syngas produced by an imbedded coal gasifier. The effect of VAM flow rate and methane concentration on the performance of CLC was analyzed thermodynamically using Aspen Plus software. Results indicated that the variations of air reactor temperature with VAM flow rate and methane concentration can be minimized as expected. The effect of temperature and inlet methane concentration on the conversion of CH was examined experimentally in a fixed bed reactor with the presence of particles of FeO/AlO. Not surprisingly, the reaction temperature put a significant influence on the conversion of CH. The conversion started at the temperature about 300 °C and the temperature to achieve full conversion was around 500 °C while the temperature in empty reactor between 665 °C and 840 °C. This is due to the catalytic effect of oxygen carriers (i.e. FeO/AlO) on the conversion of methane. Moreover, it was observed that the methane conversion rate decreased with the increase in inlet methane concentration while increasing with FeO loading content. © 2014 Elsevier Ltd. All rights reserved.
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2014 |
Ghatage SV, Peng Z, Sathe MJ, Doroodchi E, Padhiyar N, Moghtaderi B, et al., 'Stability analysis in solid-liquid fluidized beds: Experimental and computational', Chemical Engineering Journal, 256 169-186 (2014) [C1] In this study the transition from homogeneous to heterogeneous flow in a solid-liquid fluidized bed (SLFB) is examined both experimentally and numerically. The experimental appara... [more] In this study the transition from homogeneous to heterogeneous flow in a solid-liquid fluidized bed (SLFB) is examined both experimentally and numerically. The experimental apparatus comprised a refractive index-matched SLFB, comprising 5. mm diameter borosilicate glass and sodium iodine solution, which allowed for both instantaneous particle image velocimetry of the liquid flow field and solids hold-up measurements to be undertaken for superficial liquid velocities in the range of 0.06-0.22. m/s. The motion of individual, spherical steel balls (with diameters 6, 7, 8, 9. mm) was then tracked as it settled through the fluidized bed for differing superficial liquid velocities. It was observed that, for all the steel balls covered in this work, there was a change in slope in their respective classification velocity curves at a superficial liquid velocity of 0.08. m/s. This value was very close to the critical velocity of 0.085. m/s predicted from 1-D linear stability analysis; and therefore deemed to be the critical condition that marked the transition from homogeneous to non-homogenous flow. It is proposed that the change in slope of the classification velocity curve is due to the encounter of the settling foreign particles with liquid bubbles whose presence marks the onset of heterogeneous flow. Additional computational analysis, involving both Eulerian-Eulerian (E-E) and Eulerian-Lagrangian (E-L) approaches, is used to confirm the presence of liquid bubbles at a critical liquid hold-up of 0.54, which corresponds to that predicted from 1-D linear stability analysis. In summary, the study has highlighted that experimentally the transition condition for a SLFB can be obtained simply by observing the behavior of the classification velocity of a single foreign particle at different superficial liquid velocities. This transition condition was found to agree with the 1D linear stability criterion, Eulerian-Eulerian CFD (3D) and Eulerian-Lagrangian DEM (3D) approaches. © 2014 Elsevier B.V.
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2013 |
Shah K, Moghtaderi B, Zanganeh J, Wall T, 'Integration options for novel chemical looping air separation (ICLAS) process for oxygen production in oxy-fuel coal fired power plants', FUEL, 107 356-370 (2013) [C1]
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2013 |
Shah K, Moghtaderi B, Wall T, 'Effect of flue gas impurities on the performance of a chemical looping based air separation process for oxy-fuel combustion', Fuel, 103 932-942 (2013) [C1] Integrated Chemical Looping Air Separation (ICLAS) offers an energy efficient and cost effective option for large-scale oxygen generation in oxy-fuel type power plants. Oxygen pro... [more] Integrated Chemical Looping Air Separation (ICLAS) offers an energy efficient and cost effective option for large-scale oxygen generation in oxy-fuel type power plants. Oxygen production in the ICLAS is achieved by reduction of oxidised metal oxides in an environment of steam/recycled flue gas (CO2-rich) using a dedicated reduction reactor. This paper provides the results of a thermodynamic investigation into the effect of flue gas impurities on the reduction of three metal oxide oxygen carriers (Cu, Mn and Co oxides) under conditions pertinent to an oxy-fuel coal-fired power plant. Relevant calculations were carried out using the Fact-sage 6.1 thermodynamic equilibrium calculation software package. Different gas streams, namely crude/wet, dry, pure CO2 and steam were considered in the simulations together with the additional hypothetical impure flue gas stream having larger concentrations of CO, SO2 and NO. Effects of SO2, NO, CO and O2 contents of the flue gas on oxygen carrier conversion and oxygen decoupling process were investigated in detail. It was established that the successful reduction of metal oxides in the presence of flue gas impurities can only be achieved at higher temperatures due to increased partial pressure of O2 and the formation of metal sulphates at temperatures less than 800-900 °C. This may increase the operating and capital costs of the CLAS based oxygen production. © 2012 Elsevier Ltd. All rights reserved.
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2013 |
Doroodchi E, Zulfiqar H, Moghtaderi B, 'A combined experimental and theoretical study on laboratory-scale comminution of coal and biomass blends', POWDER TECHNOLOGY, 235 412-421 (2013) [C1]
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2013 |
Peng Z, Doroodchi E, Alghamdi Y, Moghtaderi B, 'Mixing and segregation of solid mixtures in bubbling fluidized beds under conditions pertinent to the fuel reactor of a chemical looping system', Powder Technology, 235 823-837 (2013) [C1] Performance of chemical looping combustion processes can be improved drastically by enhancing the overall redox characteristics of the system through the use of binary mixtures of... [more] Performance of chemical looping combustion processes can be improved drastically by enhancing the overall redox characteristics of the system through the use of binary mixtures of oxygen carriers. However, binary mixtures of oxygen carrier particles are often found to differ in both size and density and therefore have the tendency to segregate under certain operating conditions.In this work, a numerical study was conducted to investigate the mixing and segregation behaviour of binary mixtures of particles with different sizes and densities in a bubbling fluidized bed under conditions pertinent to the fuel reactor of a cold flow model (i.e. a non-reacting replica) of a 10kWth chemical looping combustor. The motion of particles was tracked individually by discrete element model (DEM), whilst the gas flow was modelled by computational fluid dynamics (CFD). Gas-particle interactions were considered by a two-way coupling method. Further, a modified version of Lacey's method was developed to calculate the mixing index, taking into account both the heterogeneity of solids spatial distribution and particle size differences.Results showed that the modified Lacey's method provided very consistent and stable mixing indexes, proving to be effective for an in-situ quantitative description of mixing. It was also found that as the size ratio of the binary mixture of particles reduced, the mixing index increased indicating better mixing conditions. The agreement between the DEM/CFD model predictions and the experimental data was found to be satisfactory. The optimum conditions for mixing of binary mixtures appeared to be a function of bubble size, bubble rising rate and bubbling dynamics (e.g., splitting and coalescence). Application of the DEM/CFD model for prediction of layer inversion phenomenon in gas-solid fluidized beds was also demonstrated. © 2012 Elsevier B.V.
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2013 |
Zhou C, Doroodchi E, Moghtaderi B, 'An in-depth assessment of hybrid solar-geothermal power generation', Energy Conversion and Management, 74 88-101 (2013) [C1]
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2013 |
Doroodchi E, Sathe M, Evans G, Moghtaderi B, 'Liquid-liquid mixing using micro-fluidised beds', Chemical Engineering Research and Design, 91 2235-2242 (2013) [C1] This study experimentally investigates the application of a solid-liquid micro-fluidised bed as a micro-mixing device. The experiments were performed in a borosilicate capillary t... [more] This study experimentally investigates the application of a solid-liquid micro-fluidised bed as a micro-mixing device. The experiments were performed in a borosilicate capillary tube with an internal diameter of 1.2. mm (i.e. near the upper-limit dimension of a micro-fluidic system) using borosilicate particles with a mean diameter of 98 µm. Refractive index matching technique using sodium iodide solution was employed to achieve a transparent fluidised bed. Mixing performance of the micro-fluidised bed in terms of mixing time was investigated using a dye dilution technique. Experiments were carried out in the creeping flow regime at Reynolds numbers ranging between 0.27 and 0.72. It was demonstrated that the micro-fluidised bed mixing time sharply decreases as the Reynolds number increases. That is because at relatively high Reynolds numbers, the particle oscillation is stronger creating larger disturbances in the flow. The energy dissipation rate in micro fluidised bed was estimated to be four orders of magnitude less than other passive micro mixers which operate in the turbulent regime. It was also demonstrated that the ratio of mixing time and the energy dissipation rate for fluidised bed micro-mixer was comparable to K-M, Tangential IMTEK, and interdigital micro-mixers. However, the fluidised bed micro-mixer was found to operate at much lower Reynolds numbers compared to other passive mixers, with a mixing time of the order of few seconds. © 2013 The Institution of Chemical Engineers.
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2013 |
Ismay MJL, Doroodchi E, Moghtaderi B, 'Effects of colloidal properties on sensible heat transfer in water-based titania nanofluids', Chemical Engineering Research and Design, 91 426-436 (2013) [C1]
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2013 |
Zanganeh J, Moghtaderi B, 'Experimental and mathematical analysis of fuel penetration through unconsolidated porous media', FIRE AND MATERIALS, 37 160-170 (2013) [C1]
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2013 |
Zanganeh J, Moghtaderi B, Ishida H, 'Combustion and flame spread on fuel-soaked porous solids', Progress in Energy and Combustion Science, 39 320-339 (2013) [C1] Fires caused by accidental spillage of flammable liquids have been a major safety concern in industries and urban areas. There has been a recent surge of interest in the research ... [more] Fires caused by accidental spillage of flammable liquids have been a major safety concern in industries and urban areas. There has been a recent surge of interest in the research concerning the combustion and flame spread over an inert porous media soaked with flammable liquid. This interest has been driven by the need to better understand fire and its behaviour under these conditions and improve the relevant fire safety and prevention technologies. A review of key studies in this subject area has been conducted and summarised, focussing mainly on the theory plus a notable experimental findings about combustion and the flame spread phenomena of fuel-soaked porous media. The review covers topics such as flame spread behaviour, physical flame propagation aspects, heat transfer, temperature distribution; and fuel consumption over inert porous media. The review concludes with some practical safety and environmental considerations for decontamination of land soaked with flammable liquid. © 2013 Elsevier Ltd. All rights reserved.
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2013 |
Zanganeh J, Moghtaderi B, 'Effect of fuel soaked time and fuel ratio on the flame spread rate over a porous bed wetted with liquid fuel', Fire Safety Journal, 59 151-159 (2013) [C1] An experimental investigation was conducted to explore the rate of flame spread over an unconsolidated porous bed of sand wetted with 2-propanol under a range of operating conditi... [more] An experimental investigation was conducted to explore the rate of flame spread over an unconsolidated porous bed of sand wetted with 2-propanol under a range of operating conditions. Video cinematography was employed to determine the rate of flame spread and characterise the combustion behaviour of the system. The rate of flame spread strongly correlated with: (i) the ratio of fuel volume to the weight of the sand bed, referred to as FR, and (ii) the flame initiation delay, referred to as FID. The rates of flame spread associated with no initiation delay cases were found to rise with increasing FR while for cases associated with any given flame initiation delay the rate of flame spread was found to decrease with increasing FR. In addition, the rate of change in flame spread was observed to be different for beds containing finer particles in comparison to those containing coarser ones. © 2013 Elsevier Ltd.
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2013 |
Alghamdi YA, Doroodchi E, Moghtaderi B, 'Mixing and segregation of binary oxygen carrier mixtures in a cold flow model of a chemical looping combustor', Chemical Engineering Journal, 223 772-784 (2013) [C1] In a typical chemical looping combustion process, the oxygen for fuel combustion is supplied by circulating metal based oxygen carriers between two interconnected fluidised bed re... [more] In a typical chemical looping combustion process, the oxygen for fuel combustion is supplied by circulating metal based oxygen carriers between two interconnected fluidised bed reactors. The redox characteristics of oxygen carriers and hence the overall performance of the process can be significantly improved by utilising binary mixtures of oxygen carrier particles. The full potential of such multi-species particle systems however can be only realised when particles segregation is minimised. This study is concerned with gaining an understanding of the mixing and segregation behaviour of binary mixtures of oxygen carrier particles with different sizes and densities in a cold flow model representing a 10. kWth chemical looping combustor. The hydrodynamics of such systems were investigated and compared with a typical chemical looping combustion process where single species are used. This was followed by investigating the solids mixing and segregation behaviour in terms of segregation intensity and species weight percentage at each reactor as a function of operating parameters. It was shown that increasing the total solid inventory, particle terminal velocity ratio, composition, and air reactor superficial velocity increases the riser pressure, solid circulation rates, and riser solid holdup. Mixing and segregation regimes of the fuel reactor and the component segregation between the two reactors were also mapped. The results showed that, for mixtures of species with low terminal velocity to high terminal velocity ratios of greater than 0.7, a good mixing in the fuel reactor can be achieved by maintaining the superficial gas velocity to the mixture minimum fluidisation velocity ratio above 5. For the tested conditions, the component segregation between the two reactors was avoided by maintaining the ratio of the riser superficial velocity to the terminal velocity of the species with a high terminal velocity between 1.25 and 2. © 2013 Elsevier B.V.
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2012 |
Moghtaderi B, 'Effects of particle cloud extinction on synthesis gas reduction of metal oxides in chemical looping reactors', Fuel, 99 262-270 (2012) [C1]
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2012 |
Moghtaderi B, 'Hydrogen enrichment of fuels using a novel miniaturised chemical looping steam reformer', Chemical Engineering Research & Design, 90 19-25 (2012) [C1]
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2012 |
Mirvakili A, Rostami M, Paymooni K, Rahimpour MR, Moghtaderi B, 'Hydrogen looping approach in optimized methanol thermally coupled membrane reactor', International Journal of Hydrogen Energy, 37 235-249 (2012) [C1]
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2012 |
Moghtaderi B, Doroodchi E, 'Performance characteristics of a miniaturised chemical looping steam reformer for hydrogen enrichment of fuels', International Journal of Hydrogen Energy, 37 15164-15169 (2012) [C1]
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2012 |
Alterman D, Moffiet TN, Hands SA, Page AW, Luo C, Moghtaderi B, 'A concept for a potential metric to characterise the dynamic thermal performance of walls', Energy and Buildings, 54 52-60 (2012) [C1]
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2012 |
Song H, Doroodchi E, Moghtaderi B, 'Redox characteristics of Fe-Ni/SiO2 bimetallic oxygen carriers in CO under conditions pertinent to chemical looping combustion', Energy & Fuels, 26 75-84 (2012) [C1]
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2012 |
Moghtaderi B, 'Review of the recent chemical looping process developments for novel energy and fuel applications', Energy & Fuels, 26 15-40 (2012) [C1]
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2012 |
Moghtaderi B, Zanganeh J, Shah KV, Wu H, 'Application of concrete and demolition waste as CO2 sorbent in chemical looping gasification of biomass', Energy & Fuels, 26 2046-2057 (2012) [C1]
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2012 |
Shah KV, Moghtaderi B, Wall TF, 'Selection of suitable oxygen carriers for chemical looping air separation: A thermodynamic approach', Energy & Fuels, 26 2038-2045 (2012) [C1]
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2012 |
Azizian MR, Doroodchi E, Moghtaderi B, 'Effect of nanoconvection caused by Brownian Motion on the enhancement of thermal conductivity in nanofluids', Industrial & Engineering Chemistry Research, 51 1782-1789 (2012) [C1]
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2012 |
Peng Z, Doroodchi E, Moghtaderi B, Evans GM, 'A DEM-based analysis of the influence of aggregate structure on suspension shear yield stress', Advanced Powder Technology, 23 437-444 (2012) [C1]
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2012 |
Fermoso J, Arias B, Moghtaderi B, Pevida C, Plaza MG, Pis JJ, Rubiera F, 'Effect of co-gasification of biomass and petroleum coke with coal on the production of gases', Greenhouse Gases: Science and Technology, 2 304-313 (2012) [C1]
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2011 |
Bayat M, Rahimpour MR, Moghtaderi B, 'Genetic algorithm strategy (GA) for optimization of a novel dual-stage slurry bubble column membrane configuration for Fischer-Tropsch synthesis in gas to liquid (GTL) technology', Journal of Natural Gas Science and Engineering, 3 555-570 (2011) [C1]
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2011 |
Rahimpour MR, Mirvakili A, Paymooni K, Moghtaderi B, 'A comparative study between a fluidized-bed and a fixed-bed water perm-selective membrane reactor with in situ H2O removal for Fischer-Tropsch synthesis of GTL technology', Journal of Natural Gas Science and Engineering, 3 484-495 (2011) [C1]
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2011 |
Zanganeh J, Moghtaderi B, 'Flame spread over porous sand beds wetted with propenol', Fire and Materials, 35 61-70 (2011) [C1]
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2011 |
Luo C, Moghtaderi B, Hands SA, Page AW, 'Determining the thermal capacitance, conductivity and the convective heat transfer coefficient of a brick wall by annually monitored temperatures and total heat fluxes', Energy and Buildings, 43 379-385 (2011) [C1]
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2011 |
Zhang YX, Doroodchi E, Moghtaderi B, 'Thermodynamic assessment of a novel concept for integrated gasification chemical looping combustion of solid fuels', Energy & Fuels, 26 287-295 (2011) [C1]
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2011 |
Iranshahi D, Pourazadi E, Paymooni K, Rahimpour MR, Jahanmiri A, Moghtaderi B, 'A dynamic membrane reactor concept for naphtha reforming, considering radial-flow patterns for both sweeping gas and reacting materials', Chemical Engineering Journal, 178 264-275 (2011) [C1]
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2011 |
Evans TM, Doroodchi E, Moghtaderi B, 'A response to Murshed et al., J Nanopart Res (2010) 12:2007-2010', Journal of Nanoparticle Research, 13 4395-4396 (2011) [C3]
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2010 |
Zanganeh J, Moghtaderi B, 'Experimental study of temperature distribution and flame spread over an inert porous bed wetted with liquid fuel', International Journal of Emerging Multidisciplinary Fluid Sciences, 2 1-14 (2010) [C1]
|
Nova | |||||||||
2010 |
Luo C, Moghtaderi B, Page AW, 'Modelling of wall heat transfer using modified conduction transfer function, finite volume and complex Fourier analysis methods', Energy and Buildings, 42 605-617 (2010) [C1]
|
Nova | |||||||||
2010 |
Moghtaderi B, 'Application of chemical looping concept for air separation at high temperatures', Energy & Fuels, 24 190-198 (2010) [C1]
|
Nova | |||||||||
2010 |
Moghtaderi B, Song H, 'Reduction properties of physically mixed metallic oxide oxygen carriers in chemical looping combustion', Energy & Fuels, 24 5359-5368 (2010) [C1]
|
Nova | |||||||||
2010 |
Ramasamy S, Moghtaderi B, 'Dielectric properties of typical Australian wood-based biomass materials at microwave frequency', Energy & Fuels, 24 4534-4548 (2010) [C1]
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Nova | |||||||||
2010 |
Luo C, Moghtaderi B, Page AW, 'Effect of ground boundary and initial conditions on the thermal performance of buildings', Applied Thermal Engineering, 30 2602-2609 (2010) [C1]
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Nova | |||||||||
2009 |
Gregory KE, Moghtaderi B, Page AW, 'Use of dissimilar walling systems on residential building envelopes for improving their thermal performance', Journal of Green Building, 4 109-125 (2009) [C1]
|
Nova | |||||||||
2009 |
Luo C, Moghtaderi B, Kennedy EM, Dlugogorski BZ, 'Three-dimensional numerical study on flames', Chemical Product and Process Modeling, 4 Article 10 (2009) [C1]
|
Nova | |||||||||
2009 |
Luo C, Dlugogorski BZ, Kennedy EM, Moghtaderi B, 'Inhibition of premixed methane-air flames with CF3I', Chemical Product and Process Modeling, 4 Article 12 (2009) [C1]
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Nova | |||||||||
2009 |
Fermoso J, Stevanov C, Moghtaderi B, Arias B, Pevida C, Plaza MG, et al., 'High-pressure gasification reactivity of biomass chars produced at different temperatures', Journal of Analytical and Applied Pyrolysis, 85 287-293 (2009) [C1]
|
Nova | |||||||||
2009 |
Wall TF, Liu Y, Spero C, Elliott LK, Khare S, Rathnam RK, et al., 'An overview on oxyfuel coal combustion: State of the art research and technology development', Chemical Engineering Research and Design, 87 1003-1016 (2009) [C1]
|
Nova | |||||||||
2009 |
Rathnam RK, Elliott LK, Wall TF, Liu Y, Moghtaderi B, 'Differences in reactivity of pulverised coal in air (O-2/N-2) and oxy-fuel (O-2/CO2) conditions', Fuel Processing Technology, 90 797-802 (2009) [C1]
|
Nova | |||||||||
2009 |
Alasha'Ary HA, Moghtaderi B, Page AW, Sugo HO, 'A neuro-fuzzy model for prediction of the indoor temperature in typical Australian residential buildings', Energy and Buildings, 41 703-710 (2009) [C1]
|
Nova | |||||||||
2009 |
Page AJ, Moghtaderi B, 'Molecular dynamics simulation of the low-temperature partial oxidation of CH4', Journal of Physical Chemistry A, 113 1539-1547 (2009) [C1]
|
Nova | |||||||||
2009 |
Doroodchi E, Evans T, Moghtaderi B, 'Comments on the effect of liquid layering on the thermal conductivity of nanofluids', Journal of Nanoparticle Research, 11 1501-1507 (2009) [C1]
|
Nova | |||||||||
2008 |
Khare S, Wall TF, Farida AZ, Liu Y, Moghtaderi B, Gupta RP, 'Factors influencing the ignition of flames from air-fired swirl pf burners retrofitted to oxy-fuel', Fuel, 87 1042-1049 (2008) [C1]
|
Nova | |||||||||
2008 |
Luo C, Moghtaderi B, Sugo HO, Page AW, 'A new stable finite volume method for predicting thermal performance of a whole building', Building and Environment, 43 37-43 (2008) [C1]
|
Nova | |||||||||
2008 |
Gregory KE, Moghtaderi B, Sugo HO, Page AW, 'Effect of thermal mass on the thermal performance of various Australian residential constructions systems', Energy and Buildings, 40 459-465 (2008) [C1]
|
Nova | |||||||||
2008 |
Luo C, Dlugogorski BZ, Moghtaderi B, Kennedy EM, 'Modified exponential schemes for convection-diffusion problems', Communications in Nonlinear Science and Numerical Simulation, 13 369-379 (2008) [C1]
|
Nova | |||||||||
2007 |
Nutalapati DB, Gupta R, Moghtaderi B, Wall TF, 'Assessing slagging and fouling during biomass combustion: A thermodynamic approach allowing for alkali/ash reactions', Fuel Processing Technology, 88 1044-1052 (2007) [C1]
|
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2007 |
Moghtaderi B, Poespowati T, Kennedy EM, Dlugogorski BZ, 'The role of extinction on the re-ignition potential of wood-based embers in bushfires', International Journal of Wildland Fire, 16 547-555 (2007) [C1]
|
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2007 |
Callen AM, Moghtaderi B, Galvin KP, 'Use of parallel inclined plates to control elutriation from a gas fluidized bed', Chemical Engineering Science, 62 356-370 (2007) [C1]
|
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2007 |
Moghtaderi B, 'Effect of enhanced mixing on partial oxidation of methane in a novel micro-reactor', Fuel, 86 469-476 (2007) [C1]
|
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2007 |
Moghtaderi B, 'A study on the char burnout characteristics of coal and biomass blends', Fuel, 86 2431-2438 (2007) [C1]
|
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2007 |
Moghtaderi B, 'Effects of controlling parameters on production of hydrogen by catalytic steam gasification of biomass at low temperatures', Fuel, 86 2422-2430 (2007) [C1]
|
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2006 |
Djenidi L, Moghtaderi B, 'Numerical investigation of laminar mixing in a coaxial microreactor', Journal of Fluid Mechanics, 568 223-242 (2006) [C1]
|
Nova | |||||||||
2006 |
Moghtaderi B, Shames I, Djenidi L, 'Microfluidic characteristics of a multi-holed baffle plate micro-reactor', International Journal of Heat and Fluid Flow, 27 1069-1077 (2006) [C1]
|
Nova | |||||||||
2006 |
Moghtaderi B, 'The state-of-the-art in pyrolysis modelling of lignocellulosic solid fuels', Fire and Materials, 30 1-34 (2006) [C1]
|
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2006 |
Zulfiqar MH, Moghtaderi B, Wall TF, 'Flow properties of biomass and coal blends', Fuel Processing Technology, 87 281-288 (2006) [C1]
|
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2006 |
Moghtaderi B, Shames I, Doroodchi E, 'Combustion prevention of iron powders by a novel coating method', Chemical Engineering & Technology, 29 97-103 (2006) [C1]
|
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2006 |
Moghtaderi B, Sheng C, Wall TF, 'An Overview of the Australian Biomass Resources and Utilization Technologies', BioResources, 1 93-115 (2006) [C1]
|
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2005 |
Cetin E, Gupta RP, Moghtaderi B, 'Effect of pyrolysis pressure and heating rate on radiata pine char structure and apparent gasification reactivity', Fuel, 84 1328-1334 (2005) [C1]
|
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2005 |
Al-Otoom A, Elliott LK, Moghtaderi B, Wall TF, 'The sintering temperature of ash, agglomeration, and defluidisation in a bench scale PFBC', Fuel, 84 109-114 (2005) [C1]
|
Nova | |||||||||
2005 |
Rezaie N, Jahanmiri A, Moghtaderi B, Rahimpour MR, 'A comparison of homogeneous and heterogeneous dynamic models for industrial methanol reactors in the presence of catalyst deactivation', Chemical Engineering and Processing, 44 911-921 (2005) [C1]
|
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2005 |
Rahimpour MR, Fathikalajahi J, Moghtaderi B, Farahani AN, 'A grade transition strategy for the prevention of melting and agglomeration of particles in an ethylene polymerization reactor', Chemical Engineering & Technology, 28 831-841 (2005) [C1]
|
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2005 |
Rahimpour MR, Moghtaderi B, Jahanmiri A, Rezaie N, 'Operability of an industrial methanol synthesis reactor with mixtures of fresh and partially deactivated catalyst', Chemical Engineering & Technology, 28 226-234 (2005) [C1]
|
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2005 |
Cetin E, Moghtaderi B, Gupta RP, Wall TF, 'Biomass gasification kinetics: Influences of pressure and char structure', Combustion Science and Technology, 177 765-791 (2005) [C1]
|
Nova | |||||||||
2004 |
Strezov V, Moghtaderi B, Lucas JA, 'Computational calorimetric investigation of the reactions during thermal conversion of wood biomass', Biomass & Bioenergy, 27 459-465 (2004) [C1]
|
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2004 |
Moghtaderi B, 'Extinction of multi-species char clouds in pulverised fuel combustors', Fuel, 83 1961-1972 (2004) [C1]
|
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2004 |
Moghtaderi B, Meesri C, Wall TF, 'Pyrolytic characteristics of blended coal and woody biomass', Fuel, 83 745-750 (2004) [C1]
|
Nova | |||||||||
2004 |
Sheng C, Moghtaderi B, Gupta RP, Wall TF, 'A computational fluid dynamics based study of the combustion characteristics of coal blends in pulverised coal-fired furnace', Fuel, 83 1543-1552 (2004) [C1]
|
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2004 |
Cetin E, Moghtaderi B, Wall TF, 'Influence of pyrolysis conditions on the structure and gasification reactivity of biomass chars', Fuel, 83 2139-2150 (2004) [C1]
|
Nova | |||||||||
2004 |
Luo C, Dlugogorski BZ, Moghtaderi B, Kennedy EM, 'Computational study on toxic gases released from compartment fires suppressed with halogenated agents', Cybernetics and Systems, 35 607-625 (2004) [C1]
|
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2004 |
Moghtaderi B, 'Application of laser Doppler velocimetry (LDV) to study the influence of heat transfer on the structure of gravity currents', Experimental Thermal and Fluid Science, 28 843-852 (2004) [C1]
|
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2003 |
Strezov V, Moghtaderi B, Lucas JA, 'Thermal Study of Decomposition of Selected Biomass Samples', Journal of Thermal Analysis and Calorimetry, 72 1041-1048 (2003) [C1]
|
Nova | |||||||||
2003 |
Meesri C, Moghtaderi B, 'Experimental and Numerical Analysis of Sawdust-Char Combustion Reactivity in a Drop Tube Reactor', Combustion Science and Technology, 175 793-823 (2003) [C1]
|
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2003 |
Al-Otoom A, Ninomiya Y, Moghtaderi B, Wall TF, 'Coal Ash Buildup on Ceramic Filters in a Hot Gas Filtration System', Energy & Fuels, 17 316-320 (2003) [C1]
|
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2002 |
Moghtaderi B, Poespowati T, Dlugogorski BZ, Kennedy EM, 'Short communication: application of a surrogate material in assessing the impact of porosity on re-ignition of wood-based materials', Fire and Materials, 26 99-101 (2002) [C1]
|
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2002 |
Meesri C, Moghtaderi B, 'Lack of synergetic effects in the pyrolytic characteristics of woody biomass/coal blends under low and high heating rate regimes', Biomass & Bioenergy, 23 56-66 (2002) [C1]
|
Nova | |||||||||
2001 |
Moghtaderi B, 'The safety implication of low heatng rate pyrolysis of coal/biomass blends in pulverised fuel boilers', Journal of Loss Prevention in the Process Industries, 14 161-165 (2001) [C1]
|
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2000 |
Moghtaderi B, 'Short communication: Effects of char oxidation on re-ignition characteristics of wood-based materials', FIRE AND MATERIALS, 24 303-304 (2000)
|
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2000 |
Moghtaderi B, 'Short communication: a methodology for evaluating the effect of drying on the heat of combustion of wood-based materials', Fire and Materials, 24 165-166 (2000)
|
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2000 |
Moghtaderi B, 'Effects of char oxidation on re-ignition characteristics of wood-based materials', Fire and Materials, 24 303-304 (2000) [C2]
|
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2000 |
Al-Otoom A, Elliott LK, Wall TF, Moghtaderi B, 'Measurements of the sintering kinetics of coal ash', Energy & Fuels, 14 994-1001 (2000) [C1]
|
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2000 |
Moghtaderi B, Dlugogorski BZ, Kennedy EM, 'Effects of wind flow on self-heating characteristics of coal stockpiles', Trans IChemE, 78, Part B 445-453 (2000) [C1]
|
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2000 |
Moghtaderi B, Dlugogorski BZ, Kennedy EM, 'A kinetic study on the production of toxic compounds in enclosure fires under suppression of halon replacement extinguishing agents', Dev Chem Eng Min Proc, 8(1/2) 113-129 (2000) [C1]
|
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2000 |
Li K, Kennedy EM, Moghtaderi B, Dlugogorski BZ, 'Experimental and computational studies on the gas-phase reaction of CBrF3 with hydrogen', Environmental Science & Technology, 34 No.4 584-590 (2000) [C1]
|
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2000 | Moghtaderi B, 'A methodology for evaluating the effect of drying on the heat of combustion of wood-based materials', Fire and Materials, 24 165-166 (2000) [C2] | ||||||||||
1999 |
Kennedy EM, Moghtaderi B, Dlugogorski BZ, 'A process for disposal of Halon 1301 (CBrF3)', Chem.Eng.Comm., 176 195-200 (1999) [C1]
|
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1999 |
Novozhilov V, Moghtaderi B, Kent JH, Fletcher DF, 'Solid fire extinguishment by a water spray', FIRE SAFETY JOURNAL, 32 119-135 (1999)
|
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1999 | Moghtaderi B, Novozhilov V, Fletcher DF, 'Transport phenomena during piloted ignition of wood', International Journal of Transport Phenomena, 1 79-96 (1999) [C1] | ||||||||||
1998 |
Moghtaderi B, Dlugogorski BZ, Kennedy EM, Fletcher DJ, 'Effects of the Structural Properties of Solid Fuels on their Re-Ignition Characteristics', Fire and Materials, 22 155-165 (1998) [C1]
|
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Show 253 more journal articles |
Conference (160 outputs)
Year | Citation | Altmetrics | Link | ||||||||
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2022 |
Namazi S, Brankovic L, Moghtaderi B, Zanganeh J, 'Predicting Deflagration and Detonation in Detonation Tube', Applications of Artificial Intelligence and Machine Learning Select Proceedings of ICAAAIML 2021, Greater Noida, India (2022) [E1]
|
Nova | |||||||||
2022 |
Peng Z, Doroodchi E, Moghtaderi B, 'Morphological and Aerodynamic Characteristics of Respirable Dust Aggregate', Xuzhou, China (2022)
|
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2022 |
Peng Z, Gai S, Moghtaderi B, Doroodchi E, 'Thermodynamic Effects of Bubble Collapse Driven by Power Ultrasound: A CFD study', Melbourne Convention and Exhibition Centre (2022)
|
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2021 |
Gai S, Peng Z, Doroodchi E, Moghtaderi B, 'Experimental study of bubble dynamics in a droplet driven by an ultrasound standing wave', Online (2021) [E1]
|
Nova | |||||||||
2021 |
Song H, Peng Z, Doroodchi E, Moghtaderi B, 'Bubble oscillation and motion in a filamentary streamer cavitation structure induced by power ultrasound', Online (2021) [E1]
|
Nova | |||||||||
2021 |
Wu S, Zhou C, Moghtaderi B, 'Use of Pressurized Oxidation of Cu2O as a Means of Improving the Performance of Redox Based Thermochemical Energy Storage Systems', PROCEEDINGS OF THE 14TH INTERNATIONAL RENEWABLE ENERGY STORAGE CONFERENCE 2020 (IRES 2020), Dusseldorf, GERMANY (2021) [E1]
|
Nova | |||||||||
2020 |
Namazi S, Brankovic L, Moghtaderi B, Zanganeh J, 'Comparative study of data mining techniques for predicting explosions in coal mines', Proceedings of the Confluence 2020 - 10th International Conference on Cloud Computing, Data Science and Engineering, Uttar Pradesh, India (2020) [E1]
|
Nova | |||||||||
2019 |
Alterman D, Page AW, Zhang C, Moghtaderi B, Albatayneh A, 'A TECHNIQUE TO ASSESS THE IMPACT ON HOUSING THERMAL PERFORMANCE OF HEAVY COMPOSITE WALLS UNDER A DYNAMIC CYCLE', BRITTLE MATRIX COMPOSITES 12, Polish Acad Sci, Inst Fundamental Technol Res, Warsaw, POLAND (2019) [E1]
|
Nova | |||||||||
2019 |
Barma M, Peng Z, Moghtaderi B, Doroodchi E, 'Freezing temperature of water drops', Chemeca 2019: Chemical Engineering Megatrends and Elements, Sydney, NSW (2019) [E1]
|
Nova | |||||||||
2018 |
Ajrash MJ, Zanganeh J, Moghtaderi B, 'Examine the Application of Venting duct on Methane and Coal Dust Explosion Characteristics', Chemeca 2018, Queenstown, New Zealand (2018) [E1]
|
Nova | |||||||||
2018 |
Albatayneh A, Alterman D, Page A, Moghtaderi B, 'The significance of the orientation on the overall buildings thermal performance-case study in Australia', Energy Procedia, Shanghai, China (2018) [E1]
|
Nova | |||||||||
2018 |
Albatayneh A, Alterman D, Page A, Moghtaderi B, 'Renewable energy systems to enhance buildings thermal performance and decrease construction costs', Energy Procedia, Shanghai, China (2018) [E1]
|
Nova | |||||||||
2018 |
Doroodchi E, Moghtaderi B, Peng Z, Mitra S, Evans G, 'Hydrodynamic behaviour of micro-fluidised beds', Newcastle, Australia (2018)
|
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2018 |
Gai S, Peng Z, Moghtaderi B, Yu J, Doroodchi E, 'Effect of ultrasonic vibration on the nucleation onset of temperature of micro-sized water droplets', Chemeca 2018, Queenstown, NZ (2018)
|
Nova | |||||||||
2017 |
Ramezani M, Tremain P, Doroodchi E, Moghtaderi B, 'Determination of carbonation/calcination reaction kinetics of a
limestone sorbent in low CO2 partial pressures using TGA
experiments', Energy Procedia, Lausanne, Switzerland (2017) [E1]
|
Nova | |||||||||
2017 |
Liu Z, Alterman D, Page A, Moghtaderi B, Chen D, 'Evaluation of slab-edge insulation on energy saving for heating and cooling slab-on-ground houses', Design to Thrive: Proceedings Volume 1: PLEA 2017 Conference, Edinburgh, U.K. (2017) [E1]
|
Nova | |||||||||
2017 |
Ajrash MJ, Zanganeh J, Moghtaderi B, 'Examine the minimum ignition energy required to ignite the coal dust cloud in ventilation air methane', 11th Asia-Pacific Conference on Combustion, ASPACC 2017, Sydney, NSW (2017) [E1]
|
Nova | |||||||||
2017 |
Shiel J, Moghtaderi B, Aynsley R, Page A, Clarke J, 'Adapting to a Warmer Climate Affordable Low-carbon Retrofits and Occupant Options for Typical Australian Houses', Proceedings of 33rd PLEA International Conference: Design to Thrive. Volume 1, Edinburgh, Scotland (2017) [E1]
|
Nova | |||||||||
2017 |
Alghamdi Y, Peng Z, Doroodchi E, Moghtaderi B, 'The Effect of Solids Holdup on the Hydrodynamic Similarity Between Lab and Scaled-Up Demonstration Pilot Plant Cold Flow Model of Chemical Looping Combustor (CFM-CLC)', The International Engineering Conference & Exhibition: Conference Proceedings, Riyadh, Saudi Arabia (2017)
|
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2017 |
Albatayneh A, Alterman D, Page A, Moghtaderi B, 'Temperature versus energy based approaches in the thermal assessment of buildings', Energy Procedia, Riga, Latvia (2017) [E1]
|
Nova | |||||||||
2017 |
Badat Y, Ajrash MJ, Zanganeh J, Moghtaderi B, 'Investigation of methane and coal dust concentration impact on explosion pressure rise in a confined spherical space', 11th Asia-Pacific Conference on Combustion, ASPACC 2017, Sydney, NSW (2017) [E1]
|
Nova | |||||||||
2017 |
Kundu SK, Zanganeh J, Eschebach D, Moghtaderi B, 'Experimental investigation of explosion characteristics of methane air mixtures in a vented vessel connected to a curved duct', 11th Asia-Pacific Conference on Combustion, ASPACC 2017, Sydney, NSW (2017) [E1]
|
Nova | |||||||||
2017 |
Tremain P, Maddocks A, Moghtaderi B, 'A pilot-scale study on the oxidation of ventilation air methane (VAM) using ilmenite', 11th Asia-Pacific Conference on Combustion, ASPACC 2017, Sydney, NSW (2017) [E1]
|
Nova | |||||||||
2017 |
Eschebach D, Zanganeh J, Moghtaderi B, 'Pressure wave and flame front positions originating from methane-air explosions in a 1m³ vessel with circular duct', 11th Asia-Pacific Conference on Combustion, ASPACC 2017, 11th Asia-Pacific Conference on Combustion, ASPACC 2017 (2017) [E1]
|
Nova | |||||||||
2017 |
Shirzaei M, Zanganeh J, Kundu S, Moghtaderi B, 'Methane-air flame propagation characteristics in presence of restriction in a duct', 11th Asia-Pacific Conference on Combustion, ASPACC 2017, Sydney, NSW (2017) [E1]
|
Nova | |||||||||
2017 |
Wu S, Zhou C, Doroodchi E, Moghtaderi B, 'A solar-assisted metal oxide redox system for peak-load shifting in coal-fired power plants', 11th Asia-Pacific Conference on Combustion, ASPACC 2017, Sydney, NSW (2017) [E1]
|
Nova | |||||||||
2017 |
Albatayneh A, Alterman D, Page A, Moghtaderi B, 'Discrepancies in Peak Temperature Times using Prolonged CFD Simulations of Housing Thermal Performance', INTERNATIONAL CONFERENCE - ALTERNATIVE AND RENEWABLE ENERGY QUEST (AREQ 2017), SPAIN (2017) [E1]
|
Nova | |||||||||
2017 |
Albatayneh A, Alterman D, Page A, Moghtaderi B, 'Thermal Assessment of Buildings Based on Occupants Behavior and the Adaptive Thermal Comfort Approach', INTERNATIONAL CONFERENCE - ALTERNATIVE AND RENEWABLE ENERGY QUEST (AREQ 2017), SPAIN (2017) [E1]
|
Nova | |||||||||
2016 |
Alterman D, Page AW, Zhang C, Moghtaderi B, 'The importance of internal thermal mass to the thermal performance of housing', Brick and Block Masonry: Trends, Innovations and Challenges - Proceedings of the 16th International Brick and Block Masonry Conference, IBMAC 2016, Padova, Italy (2016) [E1]
|
Nova | |||||||||
2016 |
Peng Z, Yuan Z, Moghtaderi B, Doroodchi E, 'Formation of water droplets by co-injection in an immiscible liquid at low temperatures', Chemeca 2016: chemical engineering - regeneration, recovery and reinvention, Adelaide, Australia (2016) [E1]
|
Nova | |||||||||
2016 |
Khan M, Mitra S, Ghatage S, Peng Z, Doroodchi E, Moghtaderi B, et al., 'Pressure drop and voidage measurement in solid-liquid fluidized bed: experimental, mathematical and computational study', CHEMECA 2016: Chemical Engineering - Regeneration, Recovery and Reinvention, Adelaide, Australia (2016) [E1]
|
Nova | |||||||||
2016 |
Khan M, Mitra S, Abbasfard H, Peng Z, Doroodchi E, Moghtaderi B, et al., 'Measurement of fluctuating velocities and dispersion behaviour of particles in a solid-liquid fluidised bed', CHEMECA 2016: Chemical Engineering - Regeneration, Recovery and Reinvention, Adelaide, Australia (2016) [E1]
|
Nova | |||||||||
2016 |
Alterman D, Page AW, Zhang C, Moghtaderi B, 'How to recognize the impact of masonry components on housing thermal performance', Brick and Block Masonry: Trends, Innovations and Challenges - Proceedings of the 16th International Brick and Block Masonry Conference, IBMAC 2016, Padova, Italy (2016) [E1]
|
Nova | |||||||||
2015 |
Khairul MA, Shah KV, Doroodchi E, Moghtaderi B, 'Application of nanofluids to enhance heat transfer in renewable energy systems', In: 3rd ASEAN Australian Engineering Congress (AAEC 2015) : Australian Engineering Congress on Innovative Technologies for Sustainable Development and Renewable Energy. Barton, ACT: Engineers Australia, 2015: 49-54., Singapore (2015) [E2]
|
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2015 |
Khan M, Mitra S, Karim I, Ghatage S, Peng Z, Doroodchi E, et al., 'Bed Expansion Behaviour in a Binary Solid-Liquid Fluidised Bed with Different Initial Solid Loading- CFD Simulation and Validation', Eleventh International Conference on CFD in the Minerals and Process Industries, Melbourne, Australia (2015) [E1]
|
Nova | |||||||||
2015 |
Peng Z, Doroodchi E, Moghtaderi B, Alghamdi Y, 'Analysis of Interaction Forces for Predicting the Transition from Segregation to Mixing of Binary Solids in a Miniaturised Gas Fluidised Bed', Asia Pacific Confederation of Chemical Engineering Congress 2015: APCChE 2015, incorporating CHEMECA 2015, Melbourne (2015) [E1]
|
Nova | |||||||||
2015 |
Alterman D, Page, Zhang C, Moghtaderi, 'The contribution of internal masonry thermal mass to the thermal performance of Australian housing', Proceedings of the 12th North American Masonry Conference, Denver, CO (2015) [E1]
|
Nova | |||||||||
2015 |
Alterman D, Page AW, Zhang C, Moghtaderi B, 'A technique to measure the impact of masonry components on housing thermal performance', Proceedings of the 12th North American Masonry Conference, University of Colorado, Denver, USA (2015) [E1]
|
Nova | |||||||||
2015 |
Khan M, Mitra S, Ghatage S, Peng Z, Doroodchi E, Moghtaderi B, et al., 'Expansion behavior of binary solid-liquid fluidised bed with different solid mass ratio', Asia Pacific Confederation of Chemical Engineering Congress 2015: APCChE 2015, incorporating CHEMECA 2015, Melbourne, Victoria (2015) [E1]
|
Nova | |||||||||
2015 |
Peng Z, Khan MD, Ghatage S, Doroodchi E, Moghtaderi B, Joshi J, Evans G, 'CFD-DEM simulation of binary systems of particles in liquid fluidised beds: segregation and dispersion', Asia Pacific Confederation of Chemical Engineering Congress 2015: APCChE 2015, incorporating CHEMECA 2015, Melbourne (2015) [E1]
|
Nova | |||||||||
2014 |
Paymooni K, Doroodchi E, Moghtaderi B, 'Simulation of perovskite membrane for integration into chemical looping air separation unit', 21st International Congress of Chemical and Process Engineering, CHISA 2014 and 17th Conference on Process Integration, Modelling and Optimisation for Energy Saving and Pollution Reduction, PRES 2014 (2014) [E1]
|
Nova | |||||||||
2013 |
Alterman D, Page AW, Moghtaderi B, Robinson J, 'Impact of insulation on the thermal performance of heavy walling systems subjected to dynamic temperature cycles', Proceedings of the 12th Canadian Masonry Symposium, Vancouver, BC (2013) [E1]
|
Nova | |||||||||
2013 |
Zanganeh J, Moghtaderi B, 'Flame Heights of an Iso-propanol Fuel Soaked Porous Bed: Experimental Study and Modelling', Proceedings of the Australian Combustion Symposium, Perth, W.A. (2013) [E1]
|
Nova | |||||||||
2013 |
Peng Z, Doroodchi E, Sathe M, Joshi J, Evans G, Moghtaderi B, 'A method for calculating the surface area of numerically simulated aggregates', Chemeca 2013, Brisbane, Qld, Australia (2013) [E1]
|
Nova | |||||||||
2012 |
Alterman D, Page AW, Hands SA, Moffiet TN, Moghtaderi B, 'A study of wall surface temperature variations for housing in moderate climates', Proceedings of the 15th International Brick and Block Masonry Conference, Florianopolis, Brazil (2012) [E1]
|
Nova | |||||||||
2012 |
Remoroza AI, Moghtaderi B, Doroodchi E, 'CO2-EGS in hot dry rock: Preliminary results from CO2-rock interaction experiments', Proceedings, Thirty-Seventh Workshop on Geothermal Reservoir Engineering, Stanford (2012) [E2]
|
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2012 |
Doroodchi E, Sathe MJ, Boyes AD, Evans GM, Moghtaderi B, 'Liquid-liquid mixing using micro-fluidised beds', Proceedings. 14th European Conference on Mixing, Warsaw, Poland (2012)
|
Nova | |||||||||
2012 |
Alghamdi YAF, Peng Z, Doroodchi E, Moghtaderi B, 'CFD-DEM simulation of particle mixing and segregation in a chemical looping combustion system under cold flow conditions', 21st International Conference on Fluidized Bed Combustion, Naples, Italy (2012) [E1]
|
Nova | |||||||||
2011 |
Alterman D, Page AW, Hands SA, Moffiet TN, Moghtaderi B, 'Looking for a true measure of the dynamic thermal response of walls and buildings', 2011 Building Australia's Future National Conference, Surfers Paradise (2011) [E3]
|
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2011 |
Alterman D, Page AW, Hands SA, Luo C, Moghtaderi B, 'Dynamic temperature profile variation through heavy and lightweight walling systems', Proceedings of the 9th Australasian Masonry Conference 2011, Queenstown (2011) [E1]
|
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2011 |
Moghtaderi B, Luo C, Alterman D, Hands SA, Page AW, Parks S, Badgery-Parker J, 'Investigation on the effect of phase changing materials on the thermal performance of a green house using the finite volume method', Proceedings of the 12th International Building Performance Simulation Association (IBPSA), Sydney (2011) [E1]
|
Nova | |||||||||
2011 |
Remoroza AI, Doroodchi E, Moghtaderi B, 'Modelling a complete C02-EGS power generation process', New Zealand Geothermal Workshop 2011 Proceedings, Rotorua, NZ (2011) [E2]
|
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2011 |
Zhou C, Doroodchi E, Munro I, Moghtaderi B, 'A feasibility study on hybrid solar-geothermal power generation', New Zealand Geothermal Workshop 2011 Proceedings, Auckland, NZ (2011) [E1]
|
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2011 |
Weir AG, Moghtaderi B, Doroodchi E, 'Improved efficiency of the carrier gas process using gases other than air', PORT2011 Proceedings, Portofino, Italy (2011) [E3]
|
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2011 |
Zanganeh J, Moghtaderi B, 'Effect of fuel ratio and flame initiation delay on the rate of flame spread over a porous bed wetted with a flammable liquid', Proceedings of the 11th Australian Combustion Symposium, Shoal Bay, NSW (2011) [E1]
|
Nova | |||||||||
2011 |
Song H, Shah KV, Doroodchi E, Moghtaderi B, 'Thermogravimetric analysis of Ni0/Si02 oxygen carriers under CO/air environment for chemical looping combustion', Proceedings of the 11th Australian Combustion Symposium, Shoal Bay, NSW (2011) [E1]
|
Nova | |||||||||
2011 | Zhang YX, Shah KV, Moghtaderi B, 'Performance characteristics of a novel integrated gasification chemical looping combustion for solid fuels', Proceedings of the 11th Australian Combustion Symposium, Shoal Bay, NSW (2011) [E1] | Nova | |||||||||
2011 |
Shah KV, Moghtaderi B, Wall TF, 'Chemical looping air separation (CLAS) for oxygen production: Thermodynamic and economic aspects', Proceedings of the Australian Combustion Symposium 2011, Shoal Bay (2011) [E1]
|
Nova | |||||||||
2011 |
Remoroza AI, Moghtaderi B, Doroodchi E, 'Coupled wellbore and 3D reservoir simulation of a CO2 EGS', Proceedings: Thirty-Sixth Workshop on Geothermal Reservoir Engineering, Stanford, CA (2011) [E2]
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2010 |
Abdul Gani ZF, Elliott LK, Liu Y, Moghtaderi B, Wall TF, 'Online monitoring of radiant emission from single burning coal particles in high temperature air and oxy-fuel environments comparison with predictions from a flame sheet model', The Proceedings of the 35th International Technical Conference on Clean Coal & Fuel Systems, Florida, USA (2010) [E1]
|
Nova | |||||||||
2010 |
Azizian MR, Doroodchi E, Moghtaderi B, 'The role of liquid layering on the enhancement of thermal conductivitiy in nanofluids', Proceedings of the 14th International Heat Transfer Conference, Washington, DC, USA (2010) [E1]
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2010 | Moghtaderi B, 'A novel miniaturised fuel reformer for on-board hydrogen enrichment of gaseous and liquid fuels in combustion systems', Chemeca 2010: Proceedings of the 40th Australasian Chemical Engineering Conference, Adelaide, Australia (2010) [E1] | Nova | |||||||||
2010 |
Moghtaderi B, Song H, 'Reaction properties of mixed metal oxides for chemical looping combustion', Chemeca 2010: Proceedings of the 40th Australasian Chemical Engineering Conference, Adelaide, Australia (2010) [E1]
|
Nova | |||||||||
2010 |
Remoroza AI, Doroodchi E, Moghtaderi B, 'Corrosion inhibition of acid-treated geothermal brine - Results from pilot testing in Southern Negros, Philippines', Proceedings World Geothermal Congress 2010, Bali, Indonesia (2010) [E1]
|
Nova | |||||||||
2009 |
Gani ZF, Moghtaderi B, Wall TF, 'Ignition characteristics of single coal particles in air (O2/N2) and oxy-fuel (O2/Co2) environments', 1st Oxyfuel Combustion Conference: Book of Abstracts, Cottbus, Germany (2009) [E2]
|
Nova | |||||||||
2009 |
Rathnam RK, Elliott LK, Liu Y, Moghtaderi B, Wall TF, Eriksson K, Stromberg L, 'Reactivity of pulverised coals in air (O2/N2) and oxy-fuel (O2/CO2) conditions', 1st Oxyfuel Combustion Conference: Book of Abstracts, Cottbus, Germany (2009) [E2]
|
Nova | |||||||||
2009 |
Ramasamy S, Moghtaderi B, 'Microwave characterization of typical Australian wood-based biomass materials', Review of Progress in Quantitative Nondestructive Evaluation: 35th Annual Review of Progress in Quantitative Nondestructive Evaluation, Chicago, ILL (2009) [E1]
|
Nova | |||||||||
2009 |
Sugo HO, Page AW, Moghtaderi B, 'The influence of wall properties on the thermal performance of Australian housing', 11th Canadian Masonry Symposium, Toronto, ONT (2009) [E1]
|
Nova | |||||||||
2009 |
Page AW, Sugo HO, Hands SA, Moghtaderi B, 'A study of the influence of wall R-value on the thermal characteristics of Australian housing', Building Australia's Future Conference Papers, Gold Coast, QLD (2009) [E1]
|
Nova | |||||||||
2009 |
Moghtaderi B, Doroodchi E, 'An overview of GRANEX technology for geothermal power generation and waste heat recovery', Proceedings of the 2009 Australian Geothermal Energy Conference, Brisbane, QLD (2009) [E2]
|
Nova | |||||||||
2009 |
Remoroza AI, Doroodchi E, Moghtaderi B, 'Power generation potential of SC-CO2 thermosiphon for engineered geothermal systems', Proceedings of the 2009 Australian Geothermal Energy Conference, Brisbane, QLD (2009) [E2]
|
Nova | |||||||||
2009 | Akbari MH, Vahabi M, Moghtaderi B, 'Three dimensional modeling of an isothermal PROX microreactor', Proceedings of the Fourth International Conference on Thermal Engineering: Theory and Applications, Abu Dhabi, UAE (2009) [E1] | Nova | |||||||||
2009 |
Zanganeh J, Moghtaderi B, 'Flame propagation over a porous media wetted with flammable liquid in a channel of finite cross section', Proceedings of the Australian Combustion Symposium 2009, Brisbane, QLD (2009) [E1]
|
Nova | |||||||||
2009 |
Moghtaderi B, 'Application of chemical looping concept for air separation at high temperatures', 2009 Sino-Australian Symposium on Advanced Coal and Biomass Utilisation Technologies, Wuhan, China (2009) [E1]
|
Nova | |||||||||
2008 |
Alasha'Ary HA, Moghtaderi B, Page AW, Sugo HO, 'Application of neuro-fuzzy model to evaluate the thermal performance of typical Australian residential masonry buildings - II', CCESD-II: 2nd Canadian Conference on Effective Design of Structures: Sustainability of Civil Engineering Structures, Hamilton, ONC (2008) [E1]
|
Nova | |||||||||
2008 |
Gregory KE, Moghtaderi B, Page AW, Sugo HO, 'Assessment of thermal performance of two masonry walling designs for housing using a combined theoretical and experimental approach', CCESD-II: 2nd Canadian Conference on Effective Design of Structures: Sustainability of Civil Engineering Structures, Hamilton, ONC (2008) [E1]
|
Nova | |||||||||
2008 | Moghtaderi B, 'The state of the art in geothermal power plant', Record - Geoscience Australia, Melbourne, VIC (2008) [E3] | ||||||||||
2008 |
Rathnam RK, Wall TF, Eriksson K, Stromberg L, Moghtaderi B, 'Reactivity of pulverised coals in simulated air (O2/N2) and oxy-fuel (O2/CO2) atmospheres', 25th International Pittsburgh Coal Conference CD-ROM Proceedings, Pittsburgh, PA (2008) [E2]
|
||||||||||
2008 |
Gregory KE, Moghtaderi B, Sugo HO, Page AW, 'A thermal performance study of common Australian residential construction systems in hypothetical modules', Proceedings of the 14th International Brick & Block Masonry Conference, Sydney, NSW (2008) [E1]
|
Nova | |||||||||
2008 |
Alasha'Ary HA, Moghtaderi B, De Dona JA, Page AW, 'Application of a neuro-fuzzy model to evaluate the thermal performance of typical Australian residential masonry buildings', Proceedings of the 14th International Brick & Block Masonry Conference, Sydney, NSW (2008) [E1]
|
Nova | |||||||||
2007 |
Moghtaderi B, Doroodchi E, 'Production of hydrogen by catalytic steam gasification of biomass at low temperatures', 15th European Biomass Conference & Exhibition - From Research to Market Deployment. Proceedings of the International Conference, Berlin (2007) [E1]
|
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2007 |
Moghtaderi B, Wall TF, 'An overview of chemical looping combustion as a potential clean coal technology', CO2CRC '07 Research Symposium Programme and Abstracts, Swan Valley, WA (2007) [E2]
|
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2007 | Moghtaderi B, 'Chemical looping', CO2CRC '07 Research Symposium Programme and Abstracts, Swan Valley, WA (2007) [E2] | ||||||||||
2007 |
McKay M, Moghtaderi B, Galvin KP, 'Drying Applications for the Reflux Classifier', CHEMECA 2007: Academia and Industry Strengthening the Profession. Proceedings, Melbourne (2007) [E1]
|
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2007 |
Brinch JF, Moghtaderi B, Galvin KP, 'Translational and rotational motion of cylinders down narrow inclined channels at low reynolds numbers', CHEMECA 2007: Academia and Industry Strengthening the Profession. Proceedings, Melbourne (2007) [E1]
|
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2007 |
MacPherson SA, Moghtaderi B, Walton KJ, Galvin KP, 'Dry processing using an air-magnetite dense medium in the reflux classifier', CHEMECA 2007: Academia and Industry Strengthening the Profession. Proceedings, Melbourne (2007) [E1]
|
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2007 |
Rathnam RK, Moghtaderi B, Wall TF, 'Differences in pulverised coal pyrolysis and char reactivity in air (O2/N2) and oxy-fuel (O2/CO2) conditions', Proceedings of the 32nd International Technical Conference on Coal Utilization & Fuel Systems. The Power of Coal, Clearwater, Florida (2007) [E2]
|
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2007 |
Khare S, Farida AZ, Wall TF, Liu Y, Moghtaderi B, Gupta RP, 'Factors influencing the ignition of flames from air fired swirl PF burners retrofitted to oxy-fuel', Proceedings of the 32nd International Technical Conference on Coal Utilization & Fuel Systems. The Power of Coal, Clearwater, Florida (2007) [E2]
|
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2007 |
Khare S, Wall TF, Farida AZ, Liu Y, Moghtaderi B, Gupta RP, 'Flame aerodynamics study on air-fired PF burners retrofitted to oxy-fuel on pilot-scale and utility scale furnaces', Proceedings: 24th Annual International Pittsburgh Coal Conference, Johannesburg, South Africa (2007) [E2]
|
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2007 |
Sugo HO, Page AW, Moghtaderi B, 'The thermal performance of cavity brick and brick veneer test modules containing a window', Proceedings - Tenth North American Masonry Conference, St. Louis, Missouri (2007) [E1]
|
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2007 |
Luo C, Moghtaderi B, Sugo HO, Page AW, 'Time lags and decrement factors under air-conditioned and free-floating conditions for multi-layer materials', 10th International Building Performance Simulation Association Conference and Exhibition-Building Simulation 2007. Proceedings, Beijing, China (2007) [E1]
|
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2007 |
Moghtaderi B, Galvin KP, 'Comparison of partial oxidation and auto-thermal reforming of methane for production of hydrogen in a novel micro-reactor', Proceedings of the Australian Combustion Symposium 2007, Sydney (2007) [E1]
|
||||||||||
2007 |
Khare S, Liu Y, Moghtaderi B, Wall TF, 'Flame aerodynamics study on air-fired PF burners retrofitted to oxy-fuel on pilot-scale and utility scale furnaces', Proceedings of the Australian Combustion Symposium 2007, Sydney (2007) [E1]
|
||||||||||
2007 |
Abdul Gani ZF, Rathnam RK, Wall TF, Moghtaderi B, 'Ignition and combustion characteristics of Australian coals in air (O2/N2) and oxy-fuel (O2/CO2) conditions', Proceedings of the Australian Combustion Symposium 2007, Sydney (2007) [E1]
|
||||||||||
2007 | Moghtaderi B, 'Techno-economic assessment of advanced technologies for power generation from biomass and coal', Proceedings of the Australian Combustion Symposium 2007, Sydney (2007) [E1] | ||||||||||
2006 |
Moghtaderi B, Djenidi L, 'Mixing Behaviour in a Novel Micro-Reactor', Australian Workshop on Fluid Mechanics, Melbourne (2006) [E3]
|
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2006 |
Ali MA, Djenidi L, Moghtaderi B, 'Lattice Boltzmann Simulation of synthetic Jet in T-Shaped Micromixer', Australian Workshop on Fluid Mechanics, Melbourne (2006) [E3]
|
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2006 |
Luo C, Moghtaderi B, Sugo HO, Page AW, 'The Verification of Finite Volume Based Thermal Performance Software using Analytical Solutions and Measurements', Proceedings of the IBPSA Australasia 2006 Conference, Adelaide (2006) [E2]
|
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2006 |
Nutalapati DB, Gupta RP, Moghtaderi B, Wall TF, 'Assessing Slagging and Fouling During Biomass Combustion: A Thermodynamic Approach Allowing for Alkali/Ash Reactions', Proceedings: Impacts of Fuel Quality on Power Production, Utah, USA (2006) [E2]
|
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2006 |
Rathnam RK, Elliott LK, Moghtaderi B, Gupta RP, Wall TF, 'Differences in Coal Reactivity in Air and Oxy-Fuel Conditions and Implications for Coal Burnout', The Proceedings of the 31st International Technical Conference on Coal Utilization & Fuel Systems, Florida, USA (2006) [E2]
|
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2005 |
Sugo HO, Page AW, Moghtaderi B, 'The Study Of Heat Flows In Masonry Walls In A Thermal Test Building Incorporating A Window', 10th Canadian Masonry Symposium, Banff, Canada (2005) [E1]
|
Nova | |||||||||
2005 |
Zulfiqar MH, Moghtaderi B, Spero C, Wall TF, 'Pilot-Scale Co-Firing of Coal and Biomass: Combustion Results from a Boiler Simulation Furnace', Proceedings of the 5th Asia-Pacific Conference on Combustion, Adelaide (2005) [E1]
|
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2005 |
Nutalapati DB, Gupta RP, Moghtaderi B, Wall TF, 'Transformations of Alkalis in Biomass Combustion', Proceedings of the 5th Asia-Pacific Conference on Combustion, Adelaide (2005) [E1]
|
||||||||||
2005 |
Moghtaderi B, Shames I, Djenidi L, 'Application of Micro-PIV Technique in Examining the Mixing Behaviour in a Novel Micro-Reactor', Proceedings of the 4th Australian Conference on Laser Diagnostics in Fluid Mechanics and Combustion, McLaren Vale, S.A. (2005) [E1]
|
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2005 | Moghtaderi B, 'Fluid Dynamic Characteristics of a Novel Micro-Reactor', The 13th Annual (International) Conference on Mechanical Engineering, Isfahan, Iran (2005) [E1] | ||||||||||
2005 |
Delichatsios MA, Wang H, Kennedy EM, Moghtaderi B, Dlugogorski BZ, 'Opposed Flame Spread in Narrow Channel Apparatus to Assist in Suppression Studies', Fire Safety Science: Proceedings of the Eighth International Symposium, Beijing (2005) [E1]
|
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2005 | Moghtaderi B, 'An Experimental Study on Catalytic Steam Gasification of Biomass at Low Temperatures', Bioenergy Australia 2005 Conference, Melbourne (2005) [E1] | ||||||||||
2005 | Moghtaderi B, 'A Combined Theoretical and Experimental Investigation of Char Burnout in Co-Firing of Coal and Biomass', MCS4, Lisbon, Portugal (2005) [E1] | ||||||||||
2005 |
Callen AM, Moghtaderi B, Galvin KP, 'Use of a Binary System of Particles to Investigate Particle Retention in a Gas Fluidised Bed Containing Parallel Inclined Plates', Particulate Systems Analysis 2005, Stratford upon Avon, U.K. (2005) [E2]
|
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2004 |
Sugo HO, Page AW, Moghtaderi B, 'Experimental Study Of The Thermal Performance Of Australian Masonry Housing - An Overview', Proceedings of the 7th Australasian Masonry Conference, Newcastle, Australia (2004) [E1]
|
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2004 |
Galvin KP, Doroodchi E, Callen AM, Moghtaderi B, Fletcher DF, Zhou ZQ, 'Development of a New Fluidized Bed Containing Inclined Plates', Proceedings, 12th International Conference on Transport & Sedimentation of Solid Particles, Prague (2004) [E1]
|
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2004 |
Page AW, Moghtaderi B, Sugo HO, 'A Comparative Study Of The Thermal Performance Of Cavity And Brick Veneer Construction', Proceedings of the 13th Internatonal Brick/Block Masonry Conference, Amsterdam (2004) [E1]
|
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2004 |
Wall TF, Gupta RP, Buhre BJ, Moghtaderi B, 'Adaptation of pf Firing and Clean Coal Technology', 13th International Conference on Coal Research, Shanghai, China (2004) [E2]
|
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2004 |
Wang H, Hicks JM, Kennedy EM, Moghtaderi B, Delichatsios MA, Dlugogorski BZ, 'Flame Spread over PMMA in Narrow Channel', 14th Annual Internatioal Halon Options Technical Working Conference (HOTWC 2004), Albuquerque, New Mexico (2004) [E2]
|
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2004 |
Callen AM, Moghtaderi B, Galvin KP, 'Retention of Particles in a High Velocity Gas Fluidised Bed Containing Parallel inclined Plates', 32nd Australasian Chemical Engineering Conference, Sydney (2004) [E1]
|
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2004 |
Wang H, Dlugogorski BZ, Hicks JM, Moghtaderi B, Delichatsios MA, Kennedy EM, 'Characterisation of Creeping Flame over PMMA in Narrow Channel', Proceedings of the Tenth International Interflame Conference, Edinburgh (2004) [E2]
|
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2004 |
Poespowati T, Moghtaderi B, Dlugogorski BZ, Kennedy EM, 'Effects of Porosity on Re-Ignition Characteristics of Wood', Proceedings of the 6th Asia-Oceania Symposium on Fire Science and Technology, Daegu, Korea (2004) [E1]
|
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2004 |
Choo TBH, Nguyen AV, Moghtaderi B, Evans GM, Dennis P, 'Influence of Cationic Polymer Conditioning on Wastewater Sludge Dewatering', Proceedings, Biosolids Specialty II Conference, Sydney (2004) [E1]
|
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2004 |
Oliver N, Dennis P, Nguyen AV, Moghtaderi B, Evans GM, Choo TBH, 'High Rate Drying Beds for Municipal Wastewater Sludge Dewatering', Proceedings, Enviro 04 Convention & Exhibition, Sydney (2004) [E1]
|
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2003 |
Luo C, Dlugogorski BZ, Moghtaderi B, Kennedy EM, 'Computational Study on Toxic Gases Released from Compartment Fires suppressed with Halogenated Agents', First International ICSC Symposium on Information Technologies in Environmental Engineering, Gdansk, Poland (2003) [E1]
|
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2003 |
Moghtaderi B, Meesri C, Wall TF, 'Pyrolytic Characteristics of Blended Coal and Woody Biomass', National Meeting & Exposition Program, New Orleans, USA (2003) [E1]
|
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2003 |
Sheng C, Moghtaderi B, Gupta RP, Wall TF, 'Computational Fluid Dynamics Modelling Combustion of Solid Fuel Blends in Pulverised Fuel-Fired Furnace', Proceedings, 12th International Conference on Coal Science, Cairns, Qld. (2003) [E2]
|
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2003 |
Sheng C, Moghtaderi B, Gupta RP, Wall TF, 'A CFD-Based Study on the Combustion Characteristics of Coal Blends', Proceedings of the 2003 Australian Symposium on Combustion & The 8th Australian Flame Days, Melbourne (2003) [E1]
|
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2003 |
Cetin E, Moghtaderi B, Gupta RP, Wall TF, 'Morphological Changes in Biomass Chars and Effect of Pyrolysis Conditions on Gasification Reactivity', Proceedings of the 2003 Australian Symposium on Combustion & The 8th Australian Flame Days, Melbourne (2003) [E1]
|
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2003 |
Callen AM, Moghtaderi B, Galvin KP, 'Particle Classification in a Novel Gas-Solid Classifier', The 31st Australasian Chemical Engineering Conference, Adelaide, S.A. (2003) [E1]
|
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2003 | Moghtaderi B, 'Application of Laser Droppler Velocimetry (LVD) to Study the Structure of Gravity Currents Under Fire Conditions', Fire Safety Science - Proceedings of the Seventh International Symposium, Worcester, Massachusetts (2003) [E1] | ||||||||||
2003 |
Moghtaderi B, Meesri C, Wall TF, 'Copyrolysis of coal and woody biomass.', ABSTRACTS OF PAPERS OF THE AMERICAN CHEMICAL SOCIETY, NEW ORLEANS, LA (2003)
|
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2003 | Williams AP, Moghtaderi B, 'A Practice Initiated Learning Strategy for Biochemical Engineering', IEE, Southampton, U.K. (2003) [E1] | ||||||||||
2002 | Moghtaderi B, Meesri C, 'Numerical analysis of coal/biomass co-firing in pulvereised fuel boilers', Ninth International Conference on Numerical Combustion, Sorrento, Italy (2002) [E2] | ||||||||||
2002 |
Gupta RP, Beacher CJ, Bhargava A, Wall TF, Moghtaderi B, Meesri C, Zulfiqar MH, 'Cofiring of coal with biomass - Significance of inorganic matter', Proceedings, Japan-Australia Coal Research Workshop, Tokyo (2002) [E2]
|
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2002 | Moghtaderi B, Meesri C, 'CFD modelling of coal/biomass co-firing', Second International Conference on Computational Fluid Dynamics, Sydney (2002) [E3] | ||||||||||
2002 | Moghtaderi B, Meesri C, 'Computational fluid dynamics (CFD) modelling of coal/biomass co-firing in pulverised fuel boilers', Proceedings, 2002 Australian Symposium on Combustion and the Seventh Australian Flame Days, Adelaide (2002) [E1] | ||||||||||
2002 |
Williams A, Moghtaderi B, Dlugogorski BZ, Kennedy EM, 'A laboratory module in biochemical engineering based ona practice initiated learning strategy', Proceedings of the 13th Annual Conference for Australasian Association for Engineering Education, Canberra (2002) [E1]
|
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2001 |
Meesri C, Moghtaderi B, Gupta RP, Rezaei H, Wall TF, 'Co-firing of biomass wth coal: combustion issues', Eighteenth Annual International Pittsburgh Coal Conference Proceedings, Newcastle, Australia (2001) [E2]
|
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2001 |
Evans GM, Jameson GJ, Moghtaderi B, 'Fifth-International Conference on Gas-Liquid and Gas-Liquid-Solid Reactor Engineerng', Chemical Engineering Science, Melbourne, Australia (2001) [E4]
|
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2001 |
Luo C, Dlugogorski BZ, Kennedy EM, Moghtaderi B, 'Alignment effect on the structure of methane - air counterflow diffusion flames', Proceedings of the 5th Asia-Oceania Symposium on Fire and Technology, Newcastle, Australia (2001) [E1]
|
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2001 |
Poespowati T, Moghtaderi B, Dlugogorski BZ, Kennedy EM, 'Effects of porosity on re-ignition characteristcs of a surrogate material', Proceedings of the 5th Asia-Oceania Symposium on Fire and Technology, Newcastle, Australia (2001) [E1]
|
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2001 | Moghtaderi B, 'Pyrolysis of char forming solid fuels: A critical review of the mathematical modelling techniques', Proceedings of the 5th Asia-Oceania Symposium on Fire and Technology, Newcastle, Australia (2001) [E1] | ||||||||||
2000 |
Luo C, Moghtaderi B, Kennedy EM, Dlugogorski BZ, 'A numerical study on the influence of inert gas shrouds on the characteristics of counterflow diffusion flames', 28th Australasian Chemical Engineering Conference, Perth (2000) [E1]
|
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2000 |
Moghtaderi B, Dlugogorski BZ, Kennedy EM, 'A method for assessing the effect of drying on heat of combustion of cellulosic materials', Proceedings of the Fourth Asia-Oceania Symposium on Fire Science and Technology, Tokyo, Japan (2000) [E3]
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2000 |
Dlugogorski BZ, Pope DM, Moghtaderi B, Kennedy EM, Lucas JA, 'A study on fire properties of Australian eucalyptus', WOOD & FIRE SAFETY, PT 1 PROCEEDINGS, STRBSKE PLESO, SLOVAKIA (2000)
|
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1999 |
Al-Otoom A, Elliott LK, Wall TF, Moghtaderi B, 'Sintering kinetics of coal ash', 1999 Australian Sumposium on Combustion and The Sixth Australian Flame Days, Newcastle (1999) [E1]
|
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1999 |
Moghtaderi B, Dlugogorski BZ, Kennedy EM, 'Proceedings of the 1999 Australian Symposium on Combustion and The Sixth Australian Flame Days', Proceedings, 1999 Australian Symposium on Combustion and The Sixth Australian Flame Days, Newcastle (1999) [E4]
|
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1999 | Moghtaderi B, 'Pyrolysis of coal/biomass blends', Proceedings, 1999 Australian Symposium on Combustion and The Sixth Australian Flame Days, Newcastle (1999) [E1] | ||||||||||
1998 |
Hirunpraditkoon S, Moghtaderi B, Dlugogorski BZ, Kennedy EM, 'Combustion Properties of a Surrogate Refuse-Derived Fuel Under Fire Conditions', Proceedings of the 26th Australasian Chemical Engineering Conference, Port Douglas, Australia (1998) [E1]
|
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1998 |
Pope DM, Moghtaderi B, Dlugogorski BZ, Kennedy EM, Lucas JA, 'Fire Properties of Blue Gum', Proceedings of the 26th Australasian Chemical Engineering Conference, Port Douglas, Australia (1998) [E1]
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1998 |
Moghtaderi B, Pope DM, Dlugogorski BZ, Kennedy EM, 'Piloted Ignition of Oil-in-Water Emulsions', Proceedings of the 26th Australasian Chemical Engineering Conference, Port Douglas, Australia (1998) [E1]
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1998 | Moghtaderi B, Fletcher DF, 'Flaming Combustion Characteristics of Wood-Based Materials', Proceedings of the Third Asia-Oceania Symposium - Fire Science and Technology, Singapore (1998) [E1] | ||||||||||
1998 |
Moghtaderi B, Dlugogorski BZ, Kennedy EM, 'Application of Detailed Chemical Kinetic Modelling to Predict the Formation of Toxic Compounds in Enclosure Fires under Suppression', Proceedings of the Third Asia-Oceania Symposium - Fire Science and Technology, Singapore (1998) [E1]
|
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1998 |
Moghtaderi B, Dlugogorski BZ, Kennedy EM, 'A Detailed Chemical Kinetic Modelling Study on High Temperature Ignition of Methane/Air Mixtures Doped with C3F7H', Proceedings, Halon Options Technical Working Conference, Albuquerque, New Mexico (1998) [E2]
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Show 157 more conferences |
Patent (3 outputs)
Year | Citation | Altmetrics | Link | ||
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2015 |
Yu J, Moghtaderi B, Integrated de-SOx and de-NOx process (2015)
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2006 |
Moghtaderi B, Doroodchi E, A Method and System for Generating Power from a Heat Source (2006) [I3]
|
||||
2006 |
Moghtaderi B, Doroodchi E, Desalination Method and Apparatus (2006) [I3]
|
Report (7 outputs)
Year | Citation | Altmetrics | Link | ||
---|---|---|---|---|---|
2020 |
Moghtaderi B, Peng Z, Zanganeh J, 'Computational Fluid Dynamics Modelling of a Generic VAM Abatement Plant: Under both Cold and Hot Flow Conditions', Centennial Coal Company Limited, 84 (2020)
|
||||
2019 |
Moghtaderi B, Peng Z, Zanganeh J, Doroodchi E, Fletcher D, 'CFD Modelling of Reverse Thermal Oxidisers for VAM Abatement:
Phase-II: CFD modelling of fixed-bed RTO devices', The Australian Coal Industry s Research Program, 70 (2019)
|
||||
2017 |
Alterman D, Page A, Moghtaderi B, 'A Study of the Thermal Performance of Australian Housing; Volume II', 100 (2017)
|
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2015 |
Moghtaderi B, Wall T, Doroodchi E, Shah K, Zhou C, Song H, 'Chemical Looping Oxygen Generation for Oxy-fuel Combustion: Final Report', Australian National Low Emissions Coal Research & Development, 94 (2015) [R1]
|
||||
2012 | Alterman D, Luo C, Moghtaderi B, Chen D, 'A study of the effect of ground heat transfer on the thermal performance of buildings', Department of Climate Change and Energy Efficiency, 35 (2012) [R2] | ||||
2012 | Alterman D, Luo C, Moghtaderi B, Chen D, 'A study of the effect of airgap on the thermal performance of buildings', Department of Climate Change and Energy Efficiency, 51 (2012) [R2] | ||||
Show 4 more reports |
Thesis / Dissertation (1 outputs)
Year | Citation | Altmetrics | Link |
---|---|---|---|
2021 | Gai S, Ultrasonic-Assisted Freezing of Micro-sized Water Droplets, The University of Newcastle (2021) |
Grants and Funding
Summary
Number of grants | 200 |
---|---|
Total funding | $90,541,812 |
Click on a grant title below to expand the full details for that specific grant.
20241 grants / $511,650
Testing of Selected Preventive and Mitigative Explosion Measures$511,650
Funding body: Anglo American Steel Making Coal Pty Ltd
Funding body | Anglo American Steel Making Coal Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2024 |
Funding Finish | 2024 |
GNo | G2400390 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
202312 grants / $24,763,565
AMMONIAC: A Chemical Looping-Based Process for Production of Green Ammonia$13,383,000
Funding body: Element 1 Pty Ltd
Funding body | Element 1 Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Laureate Professor Behdad Moghtaderi |
Scheme | Australian Trailblazer for Recycling and Clean Energy (TRaCE) Partner Funding |
Role | Lead |
Funding Start | 2023 |
Funding Finish | 2025 |
GNo | G2300617 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Achieving Negative Emissions in Production of Green Steel and Green Chemicals Using the VAMCO Family of Gas Separation Technologies$4,447,050
Funding body: Ascon Energy Pty Ltd
Funding body | Ascon Energy Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Laureate Professor Behdad Moghtaderi |
Scheme | Australian Trailblazer for Recycling and Clean Energy (TRaCE) Partner Funding |
Role | Lead |
Funding Start | 2023 |
Funding Finish | 2026 |
GNo | G2300876 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
KIMIYA – A Technology Platform for Conversion of Organic Waste to Sustainable Chemicals and Fuels$3,188,264
Funding body: ELMNTRE Pty Ltd
Funding body | ELMNTRE Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Laureate Professor Behdad Moghtaderi |
Scheme | Australian Trailblazer for Recycling and Clean Energy (TRaCE) Partner Funding |
Role | Lead |
Funding Start | 2023 |
Funding Finish | 2026 |
GNo | G2301014 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
KIMIYA – A Technology Platform for Conversion of Organic Waste to Sustainable Chemicals and Fuels$1,442,612
Funding body: Department of Education
Funding body | Department of Education |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Australian Trailblazer for Recycling and Clean Energy (ATRaCE) |
Role | Lead |
Funding Start | 2023 |
Funding Finish | 2026 |
GNo | G2301013 |
Type Of Funding | C1500 - Aust Competitive - Commonwealth Other |
Category | 1500 |
UON | Y |
Development of a Novel, Low-Cost, High Performance, Safe and Sustainable Hydrogen Storage Material$1,000,000
Funding body: LAVO Hydrogen Storage Technology Pty Ltd
Funding body | LAVO Hydrogen Storage Technology Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jamie Dickinson, Dr Poojan Modi, Laureate Professor Behdad Moghtaderi |
Scheme | Australian Trailblazer for Recycling and Clean Energy (TRaCE) Partner Funding |
Role | Lead |
Funding Start | 2023 |
Funding Finish | 2025 |
GNo | G2300680 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Prevention of Sticking in H2 fluidised bed DRI production$964,122
Funding body: HILT CRC Limited
Funding body | HILT CRC Limited |
---|---|
Project Team | Associate Professor Tom Honeyands, Associate Professor Tom Honeyands, Laureate Professor Behdad Moghtaderi, Professor Kenneth Williams, Doctor John Pye, Professor Geoffrey Brooks, Brian McDonald, Chris McMahen, Dian Olwagen |
Scheme | Research Grant |
Role | Investigator |
Funding Start | 2023 |
Funding Finish | 2026 |
GNo | G2301168 |
Type Of Funding | CRC - Cooperative Research Centre |
Category | 4CRC |
UON | Y |
Integrated facility for underground hydrogen storage research$140,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Doctor Mahshid Firouzi, Maziar Arjomandi, Professor Christoph Arns, Professor Pavel Bedrikovetski, Dr Abdelmalek Bouazza, Mr Thomas Chapman, Associate Professor Furqan Le-Hussain, Professor David Lewis, Doctor Stephan Matthai, Laureate Professor Behdad Moghtaderi, Mr Dominic Pepicelli, Doctor Samintha Perera, Doctor Mojtaba Rajabi, Doctor Ulrike Schacht, Doctor Abbas Zeinijahromi |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) |
Role | Investigator |
Funding Start | 2023 |
Funding Finish | 2023 |
GNo | G2300224 |
Type Of Funding | C1200 - Aust Competitive - ARC |
Category | 1200 |
UON | Y |
NSW Centralised Heterogeneous Minerals Processing Facility$72,001
Funding body: EcoTech Minerals Pty Ltd
Funding body | EcoTech Minerals Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Priscilla Tremain |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2023 |
Funding Finish | 2023 |
GNo | G2300476 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
To determine the heating performance and energy saving of the HeatPaint technology for a range of applications - RP$49,883
Funding body: Sydney Props Pty Ltd
Funding body | Sydney Props Pty Ltd |
---|---|
Project Team | Doctor Jafar Zanganeh, Laureate Professor Behdad Moghtaderi |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Investigator |
Funding Start | 2023 |
Funding Finish | 2024 |
GNo | G2300700 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
To determine the heating performance and energy saving of the HeatPaint technology for a range of applications - RP$49,883
Funding body: Department of Industry, Science and Resources
Funding body | Department of Industry, Science and Resources |
---|---|
Project Team | Doctor Jafar Zanganeh, Laureate Professor Behdad Moghtaderi |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Investigator |
Funding Start | 2023 |
Funding Finish | 2024 |
GNo | G2300704 |
Type Of Funding | C1500 - Aust Competitive - Commonwealth Other |
Category | 1500 |
UON | Y |
Synthesis and Application of Metal-Organic Frameworks for Carbon Dioxide (CO2) Capture$24,500
Funding body: HILT CRC Limited
Funding body | HILT CRC Limited |
---|---|
Project Team | Doctor Sam Chen, Miss Sofia Lazareva, Laureate Professor Behdad Moghtaderi |
Scheme | PhD Scholarship |
Role | Investigator |
Funding Start | 2023 |
Funding Finish | 2026 |
GNo | G2301089 |
Type Of Funding | CRC - Cooperative Research Centre |
Category | 4CRC |
UON | Y |
Thermogravimetric and differential scanning calorimetry study of lithium ores$2,250
Funding body: Novalith Technologies Pty Ltd
Funding body | Novalith Technologies Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2023 |
Funding Finish | 2023 |
GNo | G2301068 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
202211 grants / $3,413,134
Hydro Harvester - A fresh way to extract atmospheric water for drought affected communities$1,750,510
Funding body: Department of Agriculture, Water and the Environment
Funding body | Department of Agriculture, Water and the Environment |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Andrew Maddocks, Doctor Priscilla Tremain |
Scheme | Future Drought Fund Drought Resilience Innovation Grants Program - Innovation Grant |
Role | Lead |
Funding Start | 2022 |
Funding Finish | 2024 |
GNo | G2101049 |
Type Of Funding | C1500 - Aust Competitive - Commonwealth Other |
Category | 1500 |
UON | Y |
Development of a Novel Ammonia to Hydrogen Reforming Technology for Mobil and Stationary Applications$611,624
Funding body: Element Alpha Pty Ltd
Funding body | Element Alpha Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi, Doctor Cui Ying Toe, Doctor Jafar Zanganeh |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2022 |
Funding Finish | 2023 |
GNo | G2200866 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Thermal performance assessment of 7-star construction bricks$304,000
Funding body: Brickworks Building Products
Funding body | Brickworks Building Products |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Emeritus Professor Adrian Page, Doctor Jafar Zanganeh |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2022 |
Funding Finish | 2024 |
GNo | G2200869 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Hydrogen DRI Production$150,000
Funding body: BHP Billiton Marketing Asia
Funding body | BHP Billiton Marketing Asia |
---|---|
Project Team | Associate Professor Tom Honeyands, Mr Craig Garlick, Laureate Professor Behdad Moghtaderi, Doctor Khadijeh Paymooni |
Scheme | Research Grant |
Role | Investigator |
Funding Start | 2022 |
Funding Finish | 2023 |
GNo | G2200919 |
Type Of Funding | C3400 – International For Profit |
Category | 3400 |
UON | Y |
Understanding and eliminating adverse materials behaviour during and after direct reduction in shaft and fluidised bed processes $144,187
Funding body: HILT CRC Limited
Funding body | HILT CRC Limited |
---|---|
Project Team | Associate Professor Tom Honeyands, Laureate Professor Behdad Moghtaderi, Dr Mark Pownceby, Dr Suneeti Purohit |
Scheme | Research Grant |
Role | Investigator |
Funding Start | 2022 |
Funding Finish | 2023 |
GNo | G2200692 |
Type Of Funding | CRC - Cooperative Research Centre |
Category | 4CRC |
UON | Y |
Real Time Three Dimensional In-Situ Imaging of Structural Evolution of Coal During Coke Making Process Using Adaptive Electrical Capacitance Volumetric Tomography $128,755
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Arash Tahmasebi |
Scheme | Australian Coal Association Research Program (ACARP) |
Role | Lead |
Funding Start | 2022 |
Funding Finish | 2022 |
GNo | G2200267 |
Type Of Funding | C1700 - Aust Competitive - Other |
Category | 1700 |
UON | Y |
Assessing carbon utilisation and recycling opportunities for the Australian heavy industry sector from a regional hub perspective$125,597
Funding body: HILT CRC Limited
Funding body | HILT CRC Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Prof Peter Ashman, Dr Tara Hosseini, Professor David Lewis, Doctor Andrew Maddocks, Prof Greg Metha |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2022 |
Funding Finish | 2023 |
GNo | G2200272 |
Type Of Funding | CRC - Cooperative Research Centre |
Category | 4CRC |
UON | Y |
Mobile Hydrogen Energy Storage System for Defence Applications$76,000
Funding body: Hydrogen at Home Pty Ltd
Funding body | Hydrogen at Home Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2022 |
Funding Finish | 2023 |
GNo | G2200836 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Pilot Plant Relocation and 2SRC Process Studies$72,245
Funding body: EcoTech Minerals Pty Ltd
Funding body | EcoTech Minerals Pty Ltd |
---|---|
Project Team | Doctor Priscilla Tremain, Laureate Professor Behdad Moghtaderi |
Scheme | Research Grant |
Role | Investigator |
Funding Start | 2022 |
Funding Finish | 2022 |
GNo | G2200741 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Test a novel underground concrete-based seal technology.$36,500
Funding body: Department of Industry, Science, Energy and Resources
Funding body | Department of Industry, Science, Energy and Resources |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2022 |
Funding Finish | 2022 |
GNo | G2200222 |
Type Of Funding | C2100 - Aust Commonwealth – Own Purpose |
Category | 2100 |
UON | Y |
Pilot Plant Upgrade/Relocation Plan and 2SRC Process Studies$13,716
Funding body: EcoTech Mining Pty Ltd
Funding body | EcoTech Mining Pty Ltd |
---|---|
Project Team | Doctor Priscilla Tremain, Laureate Professor Behdad Moghtaderi |
Scheme | Research Grant |
Role | Investigator |
Funding Start | 2022 |
Funding Finish | 2022 |
GNo | G2200218 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
202113 grants / $1,409,384
ARC Training Centre for The Global Hydrogen Economy$569,525
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi |
Scheme | Industrial Transformation Research Hubs |
Role | Lead |
Funding Start | 2021 |
Funding Finish | 2025 |
GNo | G2000930 |
Type Of Funding | C1200 - Aust Competitive - ARC |
Category | 1200 |
UON | Y |
Airbag Explosion Suppression System for Mitigation of VAM Explosions $360,678
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh, Doctor Zhengbiao Peng |
Scheme | Australian Coal Association Research Program (ACARP) |
Role | Lead |
Funding Start | 2021 |
Funding Finish | 2023 |
GNo | G2001510 |
Type Of Funding | C1700 - Aust Competitive - Other |
Category | 1700 |
UON | Y |
ARC Training Centre for The Global Hydrogen Economy$250,000
Funding body: Southern Green Gas Limited
Funding body | Southern Green Gas Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2021 |
Funding Finish | 2025 |
GNo | G2101169 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Feasibility study on biomass ash application, H2 production and CO2 capture $49,996
Funding body: Verdant Earth Technologies Limited
Funding body | Verdant Earth Technologies Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2021 |
Funding Finish | 2021 |
GNo | G2101386 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Feasibility study on biomass ash application, H2 production and CO2 capture$49,995
Funding body: Department of Industry, Innovation and Science
Funding body | Department of Industry, Innovation and Science |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2021 |
Funding Finish | 2021 |
GNo | G2101388 |
Type Of Funding | C2200 - Aust Commonwealth – Other |
Category | 2200 |
UON | Y |
Robo-Laser: A Novel System for Remediation of Marine Corrosion in Confined Spaces Within Naval Platforms Using Laser Carrying Spider Robots$28,500
Funding body: NSW Department of Industry
Funding body | NSW Department of Industry |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Student Un-named |
Scheme | Defence Innovation Network |
Role | Lead |
Funding Start | 2021 |
Funding Finish | 2023 |
GNo | G2100609 |
Type Of Funding | C2400 – Aust StateTerritoryLocal – Other |
Category | 2400 |
UON | Y |
Feasibility and suitability assessment of the existing bins and fuel handling system$24,563
Funding body: Verdant Earth Technologies Limited
Funding body | Verdant Earth Technologies Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2021 |
Funding Finish | 2021 |
GNo | G2100906 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Feasibility study of the Goodster Waste to Energy Technology$17,400
Funding body: Goodster FMCG Pty Ltd
Funding body | Goodster FMCG Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2021 |
Funding Finish | 2022 |
GNo | G2101400 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Stone dust bag testing in Detonation Tube$16,000
Funding body: Alfabs Mining Equipment Pty Ltd
Funding body | Alfabs Mining Equipment Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2021 |
Funding Finish | 2021 |
GNo | G2100767 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Hydrogen Energy Storage system$15,400
Funding body: Hydrogen at Home Pty Ltd
Funding body | Hydrogen at Home Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2021 |
Funding Finish | 2021 |
GNo | G2101140 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Simulation and assessment of water flow rate in Aquator Class 1 (T20 and T100) manufactured by Tank Solutions company$12,500
Funding body: Tank Solutions Pty Ltd
Funding body | Tank Solutions Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh, Doctor Zhengbiao Peng |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2021 |
Funding Finish | 2021 |
GNo | G2100792 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Project Title Coal rejects characterisation and evaluation for chailings production$10,667
Funding body: SLR Consulting Australia Pty Ltd
Funding body | SLR Consulting Australia Pty Ltd |
---|---|
Project Team | Doctor Priscilla Tremain, Laureate Professor Behdad Moghtaderi |
Scheme | Research Grant |
Role | Investigator |
Funding Start | 2021 |
Funding Finish | 2021 |
GNo | G2101272 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Upgrade of EcoTech Bench-scale Apparatus Study$4,160
Funding body: EcoTech Mining Pty Ltd
Funding body | EcoTech Mining Pty Ltd |
---|---|
Project Team | Doctor Priscilla Tremain, Laureate Professor Behdad Moghtaderi |
Scheme | Research Grant |
Role | Investigator |
Funding Start | 2021 |
Funding Finish | 2021 |
GNo | G2101173 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
202018 grants / $3,210,994
Renewable methane Demonstration Project$822,000
Funding body: Southern Green Gas Limited
Funding body | Southern Green Gas Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Andrew Maddocks, Doctor Priscilla Tremain |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2020 |
Funding Finish | 2022 |
GNo | G2000581 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Adaptive Electrical Capacitance Volume Tomography for Multiphase Flows$760,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Professor Geoffrey Evans, Prof MARK Jones, Professor Craig Wheeler, Associate Professor Elham Doroodchi, Prof Graham Nathan, Professor Anh Nguyen, Professor Victor Rudolph, Prof Peter Ashman, Maziar Arjomandi, Dr Baojun Zhao, Doctor Mahshid Firouzi, Dr Mahshid Firouzi, Dr Liguang Wang, Dr Timothy Lau, Dr Nataliia Sergiienko |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) |
Role | Lead |
Funding Start | 2020 |
Funding Finish | 2020 |
GNo | G1900368 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
Efficiency Increase in Mineral Carbonation Process$440,887
Funding body: Mineral Carbonation International
Funding body | Mineral Carbonation International |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Research Project |
Role | Lead |
Funding Start | 2020 |
Funding Finish | 2023 |
GNo | G2001081 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Hydro Harvester: A novel device for atmospheric water generation using solar thermal energy and/or waste heat$330,000
Funding body: NSW Department of Planning, Industry and Environment
Funding body | NSW Department of Planning, Industry and Environment |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Andrew Maddocks, Doctor Priscilla Tremain |
Scheme | Physical Sciences Fund |
Role | Lead |
Funding Start | 2020 |
Funding Finish | 2020 |
GNo | G1901558 |
Type Of Funding | C2300 – Aust StateTerritoryLocal – Own Purpose |
Category | 2300 |
UON | Y |
Bubble Dynamics in Fine Droplets: Behaviour and Control$294,576
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Associate Professor Elham Doroodchi, Doctor Zhengbiao Peng, Laureate Professor Behdad Moghtaderi |
Scheme | Discovery Projects |
Role | Investigator |
Funding Start | 2020 |
Funding Finish | 2022 |
GNo | G1900137 |
Type Of Funding | C1200 - Aust Competitive - ARC |
Category | 1200 |
UON | Y |
GREACH- A Glass Breaching Device for Defence and Law Enforcement Applications Based on a Novel Annealing Assisted Abrasive Micro-Waterjet Cutting Approach$175,000
Funding body: NSW Department of Industry
Funding body | NSW Department of Industry |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh, A/Pro Ahmad Jabbarzadeh |
Scheme | Defence Innovation Network Pilot Project |
Role | Lead |
Funding Start | 2020 |
Funding Finish | 2020 |
GNo | G2000598 |
Type Of Funding | C2400 – Aust StateTerritoryLocal – Other |
Category | 2400 |
UON | Y |
Robo-Laser: A Novel System for Remediation of Marine Corrosion in Confined Spaces Within Naval Platforms Using Laser Carrying Spider Robots$150,000
Funding body: NSW Department of Industry
Funding body | NSW Department of Industry |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh, Professor Robert Melchers, Associate Professor Adrian Wills, Doctor Joel Ferguson, Professor Assaad Masri, Dr Matthew Dunn, Dr Shima Taheri |
Scheme | Defence Innovation Network Pilot Project |
Role | Lead |
Funding Start | 2020 |
Funding Finish | 2020 |
GNo | G1901315 |
Type Of Funding | C2300 – Aust StateTerritoryLocal – Own Purpose |
Category | 2300 |
UON | Y |
Develop a holistic understanding of the 2SRC process.$45,644
Funding body: Australian Minmet Metallurgical Laboratories Pty Ltd
Funding body | Australian Minmet Metallurgical Laboratories Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Priscilla Tremain, Doctor Cheng Zhou, Doctor Omid Mowla, Doctor Omid Mowla |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2020 |
Funding Finish | 2020 |
GNo | G2001060 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Develop a holistic understanding of the 2SRC process$45,594
Funding body: Department of Industry, Science, Energy and Resources
Funding body | Department of Industry, Science, Energy and Resources |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Priscilla Tremain, Doctor Cheng Zhou, Doctor Omid Mowla |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2020 |
Funding Finish | 2020 |
GNo | G2001181 |
Type Of Funding | C2200 - Aust Commonwealth – Other |
Category | 2200 |
UON | Y |
Performance Assessment of IntelliParticle Heating Paint$32,362
Funding body: IntelliParticle
Funding body | IntelliParticle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2020 |
Funding Finish | 2020 |
GNo | G2000370 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Recycled Biomass fuel thermal properties assessment$29,000
Funding body: Assured Environmental Pty Ltd
Funding body | Assured Environmental Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2020 |
Funding Finish | 2020 |
GNo | G2000079 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Renewable Energy Options for UHSC's Infrastructure Assets$16,800
Funding body: Upper Hunter Shire Council
Funding body | Upper Hunter Shire Council |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Prof Joe Dong, Associate Professor Kashem Muttaqi |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2020 |
Funding Finish | 2020 |
GNo | G2000875 |
Type Of Funding | C2300 – Aust StateTerritoryLocal – Own Purpose |
Category | 2300 |
UON | Y |
Mathematical Modelling of Molybdenum Dust Concentration in a Molybdenum Storage Tank$16,313
Funding body: Worley Services Pty Limited
Funding body | Worley Services Pty Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh, Doctor Zhengbiao Peng |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2020 |
Funding Finish | 2020 |
GNo | G2000965 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Investigate and validate the properties and performance of ATH$15,200
Funding body: AmpControl Service (NSW) Pty Ltd
Funding body | AmpControl Service (NSW) Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2020 |
Funding Finish | 2020 |
GNo | G2000402 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Phase 1: Coal rejects characterisation and evaluation for chailings production$10,668
Funding body: SLR Consulting Australia Pty Ltd
Funding body | SLR Consulting Australia Pty Ltd |
---|---|
Project Team | Doctor Priscilla Tremain, Laureate Professor Behdad Moghtaderi, Laureate Professor Behdad Moghtaderi |
Scheme | Research Grant |
Role | Investigator |
Funding Start | 2020 |
Funding Finish | 2020 |
GNo | G2000254 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Stone dust bag testing in Detonation Tube$10,000
Funding body: Alfabs Mining Equipment Pty Ltd
Funding body | Alfabs Mining Equipment Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2020 |
Funding Finish | 2020 |
GNo | G2001355 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
VAM abatement project status review$9,300
Funding body: Illawarra Coal Holdings Pty Ltd
Funding body | Illawarra Coal Holdings Pty Ltd |
---|---|
Project Team | Doctor Andrew Maddocks, Laureate Professor Behdad Moghtaderi |
Scheme | South32 Research Grant |
Role | Investigator |
Funding Start | 2020 |
Funding Finish | 2020 |
GNo | G2000183 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Phase II: Upscaled production of chailings for environmental analysis$7,650
Funding body: SLR Consulting Australia Pty Ltd
Funding body | SLR Consulting Australia Pty Ltd |
---|---|
Project Team | Doctor Priscilla Tremain, Laureate Professor Behdad Moghtaderi |
Scheme | Research Grant |
Role | Investigator |
Funding Start | 2020 |
Funding Finish | 2020 |
GNo | G2001077 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
201916 grants / $2,669,921
PFAS Harvester: A Technology for Destruction / Resource Recovery from PFAS$820,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi, Michael Dickson, Anh Nguyen |
Scheme | Special Research Initiatives PFAS (Per- And Poly-Fluoroalkyl Substances) Remediation |
Role | Lead |
Funding Start | 2019 |
Funding Finish | 2020 |
GNo | G1900125 |
Type Of Funding | C1200 - Aust Competitive - ARC |
Category | 1200 |
UON | Y |
Selective Absorption of Methane by Ionic Liquids (SAMIL) - Phase 2: Demonstration in Packed Bed Reactors$463,020
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Andrew Maddocks, Doctor Priscilla Tremain |
Scheme | Australian Coal Association Research Program (ACARP) |
Role | Lead |
Funding Start | 2019 |
Funding Finish | 2024 |
GNo | G1900622 |
Type Of Funding | C1700 - Aust Competitive - Other |
Category | 1700 |
UON | Y |
Computational Fluid Dynamic Modelling of a Generic VAM Abatement Plant Under Hot Flow Conditions$331,000
Funding body: Centennial Coal Company Limited - Fassifern
Funding body | Centennial Coal Company Limited - Fassifern |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh, Doctor Zhengbiao Peng, Doctor Hui Song, Doctor Cheng Zhou |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2019 |
Funding Finish | 2019 |
GNo | G1901008 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Application and Optimisation of Hybrid Chequer-Bricks in Regenerative Thermal Oxidisers for VAM Abatement$255,480
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Australian Coal Association Research Program (ACARP) |
Role | Lead |
Funding Start | 2019 |
Funding Finish | 2019 |
GNo | G1900623 |
Type Of Funding | C1700 - Aust Competitive - Other |
Category | 1700 |
UON | Y |
PFAS Harvester: A Technology for Destruction / Resource Recovery from PFAS$250,000
Funding body: Evocra Pty Ltd
Funding body | Evocra Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi, Anh Nguyen, Michael Dickson |
Scheme | Special Research Initiative Partner Funding |
Role | Lead |
Funding Start | 2019 |
Funding Finish | 2020 |
GNo | G1901040 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Simulation of VAM Fluid dynamic properties for a generic VAM abatement plant with out heat source (Cold Flow Modelling)$215,000
Funding body: Centennial Coal Company Limited - Fassifern
Funding body | Centennial Coal Company Limited - Fassifern |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh, Doctor Zhengbiao Peng, Doctor Hui Song, Doctor Cheng Zhou |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2019 |
Funding Finish | 2019 |
GNo | G1901007 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Performance and validation of stone dust bags$51,670
Funding body: Alfabs Mining Equipment Pty Ltd
Funding body | Alfabs Mining Equipment Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh, Associate Professor Phil Clausen, Mr James Bradley |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2019 |
Funding Finish | 2019 |
GNo | G1900073 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
To investigate and develop a novel and cost effective process for gold and antimony recovery$50,385
Funding body: Australian Minmet Metallurgical Laboratories Pty Ltd
Funding body | Australian Minmet Metallurgical Laboratories Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Priscilla Tremain, Doctor Jafar Zanganeh, Doctor Cheng Zhou, Associate Professor Elham Doroodchi, Doctor Omid Mowla, Associate Professor Elham Doroodchi, Doctor Omid Mowla, Doctor Priscilla Tremain, Doctor Jafar Zanganeh, Doctor Cheng Zhou |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2019 |
Funding Finish | 2019 |
GNo | G1901147 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Performance and validation of stone dust bags$50,000
Funding body: Department of Industry, Innovation and Science
Funding body | Department of Industry, Innovation and Science |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh, Doctor Jafar Zanganeh, Associate Professor Phil Clausen, Associate Professor Phil Clausen, Mr James Bradley, Mr James Bradley |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2019 |
Funding Finish | 2019 |
GNo | G1900294 |
Type Of Funding | C2200 - Aust Commonwealth – Other |
Category | 2200 |
UON | Y |
To investigate and develop a novel and cost effective process for gold and antimony recovery$50,000
Funding body: Department of Industry, Innovation and Science
Funding body | Department of Industry, Innovation and Science |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Priscilla Tremain, Doctor Jafar Zanganeh, Doctor Cheng Zhou, Associate Professor Elham Doroodchi, Doctor Omid Mowla, Associate Professor Elham Doroodchi, Doctor Omid Mowla, Doctor Priscilla Tremain, Doctor Jafar Zanganeh, Doctor Cheng Zhou |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2019 |
Funding Finish | 2019 |
GNo | G1901313 |
Type Of Funding | C2200 - Aust Commonwealth – Other |
Category | 2200 |
UON | Y |
Modelling to determine the optimum gap distance between the mine fan outlet and VAM capture duct inlet$49,000
Funding body: Centennial Coal Company Limited - Fassifern
Funding body | Centennial Coal Company Limited - Fassifern |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh, Doctor Zhengbiao Peng, Doctor Hui Song |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2019 |
Funding Finish | 2019 |
GNo | G1900573 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Performance and validation testing of stone dust bags$25,000
Funding body: Alfabs Mining Equipment Pty Ltd
Funding body | Alfabs Mining Equipment Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh, Doctor Jafar Zanganeh |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2019 |
Funding Finish | 2019 |
GNo | G1901493 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Development and testing of small stone dust bags$25,000
Funding body: Department of Industry, Innovation and Science
Funding body | Department of Industry, Innovation and Science |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2019 |
Funding Finish | 2019 |
GNo | G1901594 |
Type Of Funding | C2200 - Aust Commonwealth – Other |
Category | 2200 |
UON | Y |
Evaluation of emerging ventilation air methane abatement technologies - Phase 2$15,000
Funding body: Illawarra Coal Holdings Pty Ltd
Funding body | Illawarra Coal Holdings Pty Ltd |
---|---|
Project Team | Doctor Andrew Maddocks, Laureate Professor Behdad Moghtaderi |
Scheme | South32 Research Grant |
Role | Investigator |
Funding Start | 2019 |
Funding Finish | 2019 |
GNo | G1900967 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Sampling and analysis of the fumes emitted from the secondary layer material during the thermal process$11,520
Funding body: Regain Services Pty Ltd
Funding body | Regain Services Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Research Grants |
Role | Lead |
Funding Start | 2019 |
Funding Finish | 2019 |
GNo | G1901571 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
CD Modelling to determine the optimum length of a collapsible interface duct to quickly separate the abatement unit from the mine fan evase under abnormal conditions$7,846
Funding body: Centennial Coal Company Limited - Fassifern
Funding body | Centennial Coal Company Limited - Fassifern |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Zhengbiao Peng, Doctor Jafar Zanganeh |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2019 |
Funding Finish | 2019 |
GNo | G1900825 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
201812 grants / $748,363
Selective Adsorption of Methane by Ionic Liquids$147,320
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Australian Coal Association Research Program (ACARP) |
Role | Lead |
Funding Start | 2018 |
Funding Finish | 2018 |
GNo | G1800313 |
Type Of Funding | C1700 - Aust Competitive - Other |
Category | 1700 |
UON | Y |
Atmospheric Water Generation for Renewable Hydrogen Production$108,000
Funding body: Southern Green Gas Limited
Funding body | Southern Green Gas Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Andrew Maddocks |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2018 |
Funding Finish | 2019 |
GNo | G1801190 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
High Tech Combustion testing Facility for Evaluating Combustion Performance for Thermal Coals and Establishment of Testing Methodology$106,530
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Professor Jianglong Yu, Mr Fengkui Yin, Doctor Liza Elliott, Laureate Professor Behdad Moghtaderi |
Scheme | Australian Coal Association Research Program (ACARP) |
Role | Investigator |
Funding Start | 2018 |
Funding Finish | 2019 |
GNo | G1800028 |
Type Of Funding | C1700 - Aust Competitive - Other |
Category | 1700 |
UON | Y |
Concept Design for Pressurised Regenerative Calcium Cycle (PRC2) Energy Storage Technology$100,000
Funding body: Jord International Pty Limited
Funding body | Jord International Pty Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Dr John Warner |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2018 |
Funding Finish | 2018 |
GNo | G1800081 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Hydro Harvest Operation$62,840
Funding body: XPRIZE
Funding body | XPRIZE |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Andrew Maddocks |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2018 |
Funding Finish | 2018 |
GNo | G1800594 |
Type Of Funding | C3500 – International Not-for profit |
Category | 3500 |
UON | Y |
Assessment of Tank Solutions' Aquator Class 1 Oil Water Separator Performance$46,602
Funding body: Tank Solutions Pty Ltd
Funding body | Tank Solutions Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh, Doctor Zhengbiao Peng, Doctor Mohammad Alam, Mr Mohammed Jabbar Ajrash Al-Zuraiji |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2018 |
Funding Finish | 2018 |
GNo | G1801252 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Assessment of Tank Solutions' Aquator Class 1 Oil Water Separator Performance$46,602
Funding body: Department of Industry, Innovation and Science
Funding body | Department of Industry, Innovation and Science |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh, Doctor Zhengbiao Peng, Doctor Mohammad Alam, Mr Mohammed Jabbar Ajrash Al-Zuraiji |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2018 |
Funding Finish | 2018 |
GNo | G1900041 |
Type Of Funding | C2100 - Aust Commonwealth – Own Purpose |
Category | 2100 |
UON | Y |
Establishment of a Solar Cogeneration Plant at the Proposed Denman Tourist Park & Thermal Baths (Muswellbrook Shire)$45,867
Funding body: Muswellbrook Shire Council
Funding body | Muswellbrook Shire Council |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi, Doctor Jafar Zanganeh, Doctor Cheng Zhou |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2018 |
Funding Finish | 2018 |
GNo | G1800798 |
Type Of Funding | C2300 – Aust StateTerritoryLocal – Own Purpose |
Category | 2300 |
UON | Y |
To Validate the applicable waste heat recovery methods for reduction of energy in dishwashers$25,426
Funding body: Norris Industries Pty Ltd
Funding body | Norris Industries Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh, Doctor Ahmad Seyfaee, Doctor Mohammad Alam, Mr Yusuf Badat |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2018 |
Funding Finish | 2018 |
GNo | G1800926 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
To Validate the applicable waste heat recovery methods for reduction of energy in dishwashers$25,426
Funding body: Department of Industry, Innovation and Science
Funding body | Department of Industry, Innovation and Science |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh, Doctor Ahmad Seyfaee, Doctor Mohammad Alam, Mr Yusuf Badat |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2018 |
Funding Finish | 2019 |
GNo | G1801027 |
Type Of Funding | C2100 - Aust Commonwealth – Own Purpose |
Category | 2100 |
UON | Y |
Technical assessment of an EITE activity application$24,800
Funding body: Department of the Environment and Energy
Funding body | Department of the Environment and Energy |
---|---|
Project Team | Doctor Andrew Maddocks, Laureate Professor Behdad Moghtaderi |
Scheme | Research Grant |
Role | Investigator |
Funding Start | 2018 |
Funding Finish | 2018 |
GNo | G1800877 |
Type Of Funding | C2200 - Aust Commonwealth – Other |
Category | 2200 |
UON | Y |
A Research On Hydroxy and LPG Cutting Machine Emissions$8,950
Funding body: SCE Steel Services
Funding body | SCE Steel Services |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2018 |
Funding Finish | 2018 |
GNo | G1801018 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
201712 grants / $794,640
Stone Dust Manifold Gas Switching Thermal Swing Reactor: Abatement of VAM Streams with Ultra Low Methane Concentration Phase 4$457,700
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi |
Scheme | Australian Coal Association Research Program (ACARP) |
Role | Lead |
Funding Start | 2017 |
Funding Finish | 2018 |
GNo | G1700273 |
Type Of Funding | Aust Competitive - Non Commonwealth |
Category | 1NS |
UON | Y |
Proof of concept of the calcium looping energy storage technology$56,826
Funding body: Jord International Pty Limited
Funding body | Jord International Pty Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Andrew Maddocks, Doctor Priscilla Tremain, Doctor Cheng Zhou |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2017 |
Funding Finish | 2017 |
GNo | G1700899 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
UON 2017 Researcher Equipment Grant $40,815
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Researcher Equipment Grants |
Role | Lead |
Funding Start | 2017 |
Funding Finish | 2017 |
GNo | G1701154 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
Optimisation of Inovin water treatment technology$40,810
Funding body: Inovin Pty Ltd
Funding body | Inovin Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2017 |
Funding Finish | 2017 |
GNo | G1701004 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Optimisation of Inovin water treatment technology$40,810
Funding body: Department of Industry, Innovation and Science
Funding body | Department of Industry, Innovation and Science |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2017 |
Funding Finish | 2017 |
GNo | G1701134 |
Type Of Funding | C2100 - Aust Commonwealth – Own Purpose |
Category | 2100 |
UON | Y |
Identification and assessment of emerging ventilation air methane abatement technologies$30,000
Funding body: South32
Funding body | South32 |
---|---|
Project Team | Doctor Andrew Maddocks, Laureate Professor Behdad Moghtaderi |
Scheme | Research Grant |
Role | Investigator |
Funding Start | 2017 |
Funding Finish | 2017 |
GNo | G1700162 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
UoN Technical Assistance for the PacWaste Contingency for Disaster Waste (Green Waste Utilisation)$28,967
Funding body: Secretariat of the Pacific Regional Environment Programme (SPREP)
Funding body | Secretariat of the Pacific Regional Environment Programme (SPREP) |
---|---|
Project Team | Doctor Dusan Ilic, Professor Kenneth Williams, Doctor Wei Chen, Doctor Jie Guo, Laureate Professor Behdad Moghtaderi, Emeritus Professor Mark Jones, Doctor Geoffrey Doherty |
Scheme | Request for Tender |
Role | Investigator |
Funding Start | 2017 |
Funding Finish | 2017 |
GNo | G1601540 |
Type Of Funding | C3500 – International Not-for profit |
Category | 3500 |
UON | Y |
Optimisation of the anodising treatment technology process$24,937
Funding body: Speedflow Products Pty Ltd
Funding body | Speedflow Products Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2017 |
Funding Finish | 2017 |
GNo | G1701121 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Optimisation of the anodising treatment technology process$24,937
Funding body: Department of Industry, Innovation and Science
Funding body | Department of Industry, Innovation and Science |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2017 |
Funding Finish | 2017 |
GNo | G1701122 |
Type Of Funding | C2200 - Aust Commonwealth – Other |
Category | 2200 |
UON | Y |
Research and recommend a range of options for new methods of off-grid energy production$21,258
Funding body: Department of Industry, Innovation and Science
Funding body | Department of Industry, Innovation and Science |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2017 |
Funding Finish | 2018 |
GNo | G1701252 |
Type Of Funding | C2100 - Aust Commonwealth – Own Purpose |
Category | 2100 |
UON | Y |
Impact of foam with encapsulated PCM beads to minimalise the heat transfer on the internal environment$15,000
Funding body: NSW Department of Industry
Funding body | NSW Department of Industry |
---|---|
Project Team | Doctor Dariusz Alterman, Laureate Professor Behdad Moghtaderi |
Scheme | TechVoucher Program |
Role | Investigator |
Funding Start | 2017 |
Funding Finish | 2017 |
GNo | G1701208 |
Type Of Funding | C2400 – Aust StateTerritoryLocal – Other |
Category | 2400 |
UON | Y |
Research and recommend a range of options for new methods of off-grid energy production$12,580
Funding body: Milltech Pty Limited
Funding body | Milltech Pty Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2017 |
Funding Finish | 2018 |
GNo | G1701464 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
201612 grants / $2,245,484
Combining Redox Energy Storage With Coal-Fired Power Generation: A Novel Approach to Manage Variable Load Without the Need to Cycle Coal-Fired Generating Units $383,663
Funding body: NSW Department of Industry Skills and Regional Development
Funding body | NSW Department of Industry Skills and Regional Development |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi, Professor Jianglong Yu |
Scheme | Coal Innovation NSW Fund |
Role | Lead |
Funding Start | 2016 |
Funding Finish | 2018 |
GNo | G1700260 |
Type Of Funding | C2300 – Aust StateTerritoryLocal – Own Purpose |
Category | 2300 |
UON | Y |
Scope study of technological options for SOx treatment for CTSCo project $377,949
Funding body: Australian National Low Emissions Coal Research & Development
Funding body | Australian National Low Emissions Coal Research & Development |
---|---|
Project Team | Professor Jianglong Yu, Emeritus Professor Terry Wall, Doctor Rohan Stanger, Associate Professor John Lucas, Laureate Professor Behdad Moghtaderi, Dr Hai Yu, Dr Lianbo Liu, Dr Hongwei Niu |
Scheme | Research Project |
Role | Investigator |
Funding Start | 2016 |
Funding Finish | 2017 |
GNo | G1600812 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Computational Fluid Dynamics (CFD) Modelling of Reverse Thermal Oxidisers or VAM Abatement; Phase I$361,520
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi |
Scheme | Australian Coal Association Research Program (ACARP) |
Role | Lead |
Funding Start | 2016 |
Funding Finish | 2018 |
GNo | G1601254 |
Type Of Funding | Aust Competitive - Non Commonwealth |
Category | 1NS |
UON | Y |
SDL process at 1m3/s of VAM flow rate: Phase 3 (C23052 Extension)$352,865
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Dr Kalpit Shah |
Scheme | Australian Coal Association Research Program (ACARP) |
Role | Lead |
Funding Start | 2016 |
Funding Finish | 2017 |
GNo | G1500815 |
Type Of Funding | Aust Competitive - Non Commonwealth |
Category | 1NS |
UON | Y |
Demonstration of a 1MQh/day Novel Chemical Looping Based Redox Energy Storage System$278,800
Funding body: Infratech Industries Pty Ltd
Funding body | Infratech Industries Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Dr Kalpit Shah |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2016 |
Funding Finish | 2022 |
GNo | G1600828 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Innovative Integrated Combustion Flue Gas Dry Cleaning Technology$239,539
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Professor Jianglong Yu, Laureate Professor Behdad Moghtaderi, Professor Qingbo Meng, Meng, Qingbo |
Scheme | Linkage Projects |
Role | Investigator |
Funding Start | 2016 |
Funding Finish | 2019 |
GNo | G1501181 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Innovative Integrated Combustion Flue Gas Dry Cleaning Technology$102,000
Funding body: Sinosteel Anshan Research Institute of Thermo-Energy Co. Ltd
Funding body | Sinosteel Anshan Research Institute of Thermo-Energy Co. Ltd |
---|---|
Project Team | Professor Jianglong Yu, Laureate Professor Behdad Moghtaderi, Professor Qingbo Meng, Meng, Qingbo |
Scheme | Linkage Projects Partner Funding |
Role | Investigator |
Funding Start | 2016 |
Funding Finish | 2019 |
GNo | G1501354 |
Type Of Funding | C3400 – International For Profit |
Category | 3400 |
UON | Y |
Innovations Connections: Advanced Process Simulation Research for Thermochemical Energy Storage$50,000
Funding body: Department of Industry, Innovation and Science
Funding body | Department of Industry, Innovation and Science |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi, Dr Rajesh Nellore |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2016 |
Funding Finish | 2016 |
GNo | G1601319 |
Type Of Funding | C2100 - Aust Commonwealth – Own Purpose |
Category | 2100 |
UON | Y |
Innovations Connections: Advanced Process Simulation Research for Thermochemical Energy Storage$50,000
Funding body: Infratech Industries Pty Ltd
Funding body | Infratech Industries Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi, Dr Rajesh Nellore |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2016 |
Funding Finish | 2016 |
GNo | G1700464 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Research into and Validation of Hydroxy Cutting Technology$17,074
Funding body: Integrated Steelmill Sevices Pty Ltd
Funding body | Integrated Steelmill Sevices Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2016 |
Funding Finish | 2016 |
GNo | G1601226 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Safety and Compliance Testing of Hydroxy Cutting Technologies$17,074
Funding body: Department of Industry, Innovation and Science
Funding body | Department of Industry, Innovation and Science |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Entrepreneurs' Programme: Innovation Connections |
Role | Lead |
Funding Start | 2016 |
Funding Finish | 2016 |
GNo | G1601228 |
Type Of Funding | C2100 - Aust Commonwealth – Own Purpose |
Category | 2100 |
UON | Y |
Research pre-feasibility study on the effect of phase change materials on the thermal performance of housing for development of new building materials$15,000
Funding body: Infratech Industries Pty Ltd
Funding body | Infratech Industries Pty Ltd |
---|---|
Project Team | Doctor Dariusz Alterman, Laureate Professor Behdad Moghtaderi |
Scheme | Research Grant |
Role | Investigator |
Funding Start | 2016 |
Funding Finish | 2016 |
GNo | G1600472 |
Type Of Funding | Grant - Aust Non Government |
Category | 3AFG |
UON | Y |
20151 grants / $235,650
Development of a Novel Stone Dust Looping Process for Mitigation of Ventilation Air Methane (Phase II)$235,650
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Doctor Kalpit Shah, Laureate Professor Behdad Moghtaderi |
Scheme | Australian Coal Association Research Program (ACARP) |
Role | Lead |
Funding Start | 2015 |
Funding Finish | 2016 |
GNo | G1400713 |
Type Of Funding | Aust Competitive - Non Commonwealth |
Category | 1NS |
UON | Y |
20146 grants / $18,471,869
VAM Abatement Safety Project$12,499,348
Funding body: ACALET (ACA Low Emissions Technologies Ltd)
Funding body | ACALET (ACA Low Emissions Technologies Ltd) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Jafar Zanganeh, Mr Patrick Booth, Mr Jim Sandford, Mrs Behnaz Rahmatmand |
Scheme | COAL21 Fund |
Role | Lead |
Funding Start | 2014 |
Funding Finish | 2017 |
GNo | G1400523 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Chemical Looping VAM Abatement Project$2,730,000
Funding body: ACALET (ACA Low Emissions Technologies Ltd)
Funding body | ACALET (ACA Low Emissions Technologies Ltd) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi, Mr Jim Sandford, Dr Kalpit Shah |
Scheme | COAL21 Fund |
Role | Lead |
Funding Start | 2014 |
Funding Finish | 2017 |
GNo | G1400521 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Chemical Looping VAM Abatement Project$2,730,000
Funding body: ACALET (ACA Low Emissions Technologies Ltd)
Funding body | ACALET (ACA Low Emissions Technologies Ltd) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi, Mr Jim Sandford, Dr Kalpit Shah |
Scheme | COAL21 Fund |
Role | Lead |
Funding Start | 2014 |
Funding Finish | 2017 |
GNo | G1400521 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
A Novel Hybrid Chemical Looping Process for Production of Liquid Hydrocarbon Fuels with a Reduced Greenhouse Gas Emissions Profile$283,085
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Emeritus Professor Terry Wall, Dr Kalpit Shah |
Scheme | Discovery Projects |
Role | Lead |
Funding Start | 2014 |
Funding Finish | 2016 |
GNo | G1300530 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Development of a Novel Stone Dust Looping Process for Mitigation of Ventilation Air Methane$173,747
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Dr Kalpit Shah |
Scheme | Australian Coal Association Research Program (ACARP) |
Role | Lead |
Funding Start | 2014 |
Funding Finish | 2015 |
GNo | G1300819 |
Type Of Funding | Aust Competitive - Non Commonwealth |
Category | 1NS |
UON | Y |
Scoping study on next generation approaches for effective mitigation of ventilation air methane: VAM Abatement Technology Assessment Tool$55,689
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Kalpit Shah |
Scheme | Australian Coal Association Research Program (ACARP) |
Role | Lead |
Funding Start | 2014 |
Funding Finish | 2014 |
GNo | G1300818 |
Type Of Funding | Aust Competitive - Non Commonwealth |
Category | 1NS |
UON | Y |
20134 grants / $15,318,948
VAM Abatement Safety Project$12,499,348
Funding body: Department of Resources Energy and Tourism
Funding body | Department of Resources Energy and Tourism |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Coal Mining Abatement Technology Support Package (CMATSP) |
Role | Lead |
Funding Start | 2013 |
Funding Finish | 2016 |
GNo | G1201029 |
Type Of Funding | C2100 - Aust Commonwealth – Own Purpose |
Category | 2100 |
UON | Y |
Chemical Looping VAM Abatement$2,730,000
Funding body: Department of Resources Energy and Tourism
Funding body | Department of Resources Energy and Tourism |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi, Mr Jim Sandford |
Scheme | Coal Mining Abatement Technology Support Package (CMATSP) |
Role | Lead |
Funding Start | 2013 |
Funding Finish | 2016 |
GNo | G1201041 |
Type Of Funding | C2100 - Aust Commonwealth – Own Purpose |
Category | 2100 |
UON | Y |
Empirical and theoretical modelling of house slab edge insulation$78,000
Funding body: CSIRO - Commonwealth Scientific and Industrial Research Organisation
Funding body | CSIRO - Commonwealth Scientific and Industrial Research Organisation |
---|---|
Project Team | Doctor Dariusz Alterman, Laureate Professor Behdad Moghtaderi, Emeritus Professor Adrian Page, Mr Dong Chen |
Scheme | Postgraduate Scholarship |
Role | Investigator |
Funding Start | 2013 |
Funding Finish | 2017 |
GNo | G1300697 |
Type Of Funding | C2100 - Aust Commonwealth – Own Purpose |
Category | 2100 |
UON | Y |
2013 International Visitor - Kiel and Van der Drift$11,600
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Emeritus Professor Terry Wall, Doctor Kalpit Shah, Professor Jacob Kiel, Dr A (Bram) van der Drift |
Scheme | DVCR International Visitor Support |
Role | Lead |
Funding Start | 2013 |
Funding Finish | 2013 |
GNo | G1301109 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
20127 grants / $1,357,400
Development of a Measure for Assessment of the Dynamic Thermal Response of Buildings$445,000
Funding body: Think Brick Australia
Funding body | Think Brick Australia |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Emeritus Professor Adrian Page, PhD student |
Scheme | Linkage Projects Partner Funding |
Role | Lead |
Funding Start | 2012 |
Funding Finish | 2017 |
GNo | G1100712 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Simultaneous Measurements of Reaction Kinetics and Particle Distributions for Cutting-Edge Research into CO2 Storage, Catalysis and Novel Materials$200,000
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Conjoint Professor Bogdan Dlugogorski, Professor Eric Kennedy, Laureate Professor Behdad Moghtaderi, Professor Michael Stockenhuber, Professor Robert Melchers, Lprof SCOTT Sloan |
Scheme | Equipment Grant |
Role | Investigator |
Funding Start | 2012 |
Funding Finish | 2012 |
GNo | G1100634 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
ACARP Ventilation Air Methane Project$200,000
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Australian Coal Association Research Program (ACARP) |
Role | Lead |
Funding Start | 2012 |
Funding Finish | 2013 |
GNo | G1101077 |
Type Of Funding | Aust Competitive - Non Commonwealth |
Category | 1NS |
UON | Y |
Simultaneous Measurements of Reaction Kinetics and Particle Distributions for Cutting-Edge Research into CO2 Storage, Catalysis and Novel Materials$160,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Conjoint Professor Bogdan Dlugogorski, Professor Eric Kennedy, Laureate Professor Behdad Moghtaderi, Professor Michael Stockenhuber, Professor Robert Melchers, Dr Ali Abbas, Associate Professor Marjorie Valix, Associate Professor Andrew Harris, Dr Gallage Kannangara, Professor John Bartlett, Dr Adriyan Milev, Dr Nguyen Tran, Professor Eric May, Associate Professor Thomas Rufford, Associate Professor Brian O'Neill |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) |
Role | Investigator |
Funding Start | 2012 |
Funding Finish | 2012 |
GNo | G1100806 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
Simultaneous Measurements of Reaction Kinetics and Particle Distributions for Cutting-Edge Research into CO2 Storage, Catalysis and Novel Materials$160,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Conjoint Professor Bogdan Dlugogorski, Professor Eric Kennedy, Laureate Professor Behdad Moghtaderi, Professor Michael Stockenhuber, Professor Robert Melchers, Dr Ali Abbas, Associate Professor Marjorie Valix, Associate Professor Andrew Harris, Dr Gallage Kannangara, Professor John Bartlett, Dr Adriyan Milev, Dr Nguyen Tran, Professor Eric May, Associate Professor Thomas Rufford, Associate Professor Brian O'Neill |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) Partner Funding |
Role | Investigator |
Funding Start | 2012 |
Funding Finish | 2012 |
GNo | G1200631 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
Advanced biomass gasification process for distributed power generation with significant negative carbon emission in rural and regional Australia$157,400
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Professor Hongwei Wu, Laureate Professor Behdad Moghtaderi, Professor Jun-ichiro Hayashi |
Scheme | Discovery Projects |
Role | Lead |
Funding Start | 2012 |
Funding Finish | 2014 |
GNo | G1101154 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
A facility for non-destructive quantification of coal structures, composition and percolation fluid flows in energy and environmental applications$35,000
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Professor Anh Nguyen, Professor Victor Rudolph, Professor Suresh Bhatia, Professor John Zhu, Dr Simon Smart, Professor Dongke Zhang, Professor Hui Tong Chua, Doctor Roberto Moreno-Atanasio, Professor Geoffrey Evans, Laureate Professor Kevin Galvin, Emeritus Professor Graeme Jameson, Laureate Professor Behdad Moghtaderi, Associate Professor Qin Li, Dr Shaobin Wang, Dr Chi Phan, Associate Professor Shaomin Liu |
Scheme | Equipment Grant |
Role | Investigator |
Funding Start | 2012 |
Funding Finish | 2012 |
GNo | G1100623 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
20115 grants / $1,348,921
Xstrata Chemical Looping (XCL) Research Project$610,239
Funding body: Xstrata Coal Low Emissions Research and Development Corporation Pty Limited
Funding body | Xstrata Coal Low Emissions Research and Development Corporation Pty Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Professor Alan Broadfoot |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2011 |
Funding Finish | 2013 |
GNo | G1100645 |
Type Of Funding | Grant - Aust Non Government |
Category | 3AFG |
UON | Y |
Chemical Looping Oxygen Generation for Oxy-fuel Combustion and Gasification$295,856
Funding body: Australian National Low Emissions Coal Research & Development
Funding body | Australian National Low Emissions Coal Research & Development |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Alternatives & Fundamentals Program |
Role | Lead |
Funding Start | 2011 |
Funding Finish | 2012 |
GNo | G1100758 |
Type Of Funding | Aust Competitive - Non Commonwealth |
Category | 1NS |
UON | Y |
A Detailed Techno-Economic Assessment of the Geothermal Assisted Power Generation Concept$271,826
Funding body: Xstrata Coal Low Emissions Research and Development Corporation Pty Limited
Funding body | Xstrata Coal Low Emissions Research and Development Corporation Pty Limited |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2011 |
Funding Finish | 2011 |
GNo | G1100922 |
Type Of Funding | Grant - Aust Non Government |
Category | 3AFG |
UON | Y |
Production, Processing and Combustion of an Innovative Slurry Fuel for High Efficiency Distributed Power $105,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Professor Dongke Zhang |
Scheme | Discovery Projects |
Role | Lead |
Funding Start | 2011 |
Funding Finish | 2013 |
GNo | G1001061 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Char from black coal tailings for fertiliser and carbon storage$66,000
Funding body: NSW Environmental Trust
Funding body | NSW Environmental Trust |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Judy Bailey, Associate Professor Gregory Hancock, Dr Lyndal Hugo |
Scheme | Environmental Research (Minor Grant) |
Role | Lead |
Funding Start | 2011 |
Funding Finish | 2013 |
GNo | G1000090 |
Type Of Funding | Other Public Sector - State |
Category | 2OPS |
UON | Y |
20109 grants / $2,543,918
A novel chemical looping based air separation technology for Oxy-fuel combustion of coal$886,618
Funding body: NSW Trade & Investment
Funding body | NSW Trade & Investment |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Emeritus Professor Terry Wall |
Scheme | Coal Innovation NSW Fund |
Role | Lead |
Funding Start | 2010 |
Funding Finish | 2012 |
GNo | G1000643 |
Type Of Funding | Other Public Sector - State |
Category | 2OPS |
UON | Y |
A Novel Approach for Chemical Looping Gasification of Municipal Solid Waste$375,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Linkage Projects |
Role | Lead |
Funding Start | 2010 |
Funding Finish | 2013 |
GNo | G0900182 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
A Novel Approach for Chemical Looping Gasification of Municipal Solid Waste$300,000
Funding body: N Moit & Sons (NSW) Pty Ltd
Funding body | N Moit & Sons (NSW) Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Linkage Projects Partner Funding |
Role | Lead |
Funding Start | 2010 |
Funding Finish | 2012 |
GNo | G0900199 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Application of Tuneable Nanofluids in Regenerative Supercritical Power Generation$290,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi, Mr Ian Munro |
Scheme | Linkage Projects |
Role | Lead |
Funding Start | 2010 |
Funding Finish | 2013 |
GNo | G0900183 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Application of Tuneable Nanofluids in Regenerative Supercritical Power Generation$240,000
Funding body: Granite Power Pty Ltd
Funding body | Granite Power Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi, Mr Ian Munro |
Scheme | Linkage Projects Partner Funding |
Role | Lead |
Funding Start | 2010 |
Funding Finish | 2012 |
GNo | G0900200 |
Type Of Funding | Grant - Aust Non Government |
Category | 3AFG |
UON | Y |
Enhanced Waste Heat Recovery from Low-grade Heat Sources using a Novel Supercritical Power Cycle$228,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi, Mr Ian Munro |
Scheme | Linkage Projects |
Role | Lead |
Funding Start | 2010 |
Funding Finish | 2011 |
GNo | G0190488 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Enhanced Waste Heat Recovery from Low-grade Heat Sources using a Novel Supercritical Power Cycle$150,000
Funding body: Granite Power Pty Ltd
Funding body | Granite Power Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi, Mr Ian Munro |
Scheme | Linkage Projects Partner Funding |
Role | Lead |
Funding Start | 2010 |
Funding Finish | 2011 |
GNo | G0190508 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Phase change materials greenhouse study$48,300
Funding body: NSW Trade & Investment
Funding body | NSW Trade & Investment |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Doctor Dariusz Alterman, Doctor Caimao Luo |
Scheme | Gosford Horticultural Institute |
Role | Lead |
Funding Start | 2010 |
Funding Finish | 2010 |
GNo | G1001069 |
Type Of Funding | Other Public Sector - State |
Category | 2OPS |
UON | Y |
Newcastle Port Corporation - uni contribution$26,000
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Special Project (Equipment) Grant |
Role | Lead |
Funding Start | 2010 |
Funding Finish | 2010 |
GNo | G1000852 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
20092 grants / $56,500
Newcastle Port Corporation - uni contribution$36,500
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Emeritus Professor Terry Wall |
Scheme | Internal Research Support |
Role | Lead |
Funding Start | 2009 |
Funding Finish | 2010 |
GNo | G0190018 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
University (DVCR) contribution to Think Brick$20,000
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Internal Research Support |
Role | Lead |
Funding Start | 2009 |
Funding Finish | 2010 |
GNo | G0190020 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
20082 grants / $175,000
Thermal performance of buildings$160,000
Funding body: Think Brick Australia
Funding body | Think Brick Australia |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Fellowship Grant |
Role | Lead |
Funding Start | 2008 |
Funding Finish | 2009 |
GNo | G0188631 |
Type Of Funding | Grant - Aust Non Government |
Category | 3AFG |
UON | Y |
A laser facility for imaging the time evolution of scalars in turbulent flow$15,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) |
Role | Lead |
Funding Start | 2008 |
Funding Finish | 2008 |
GNo | G0189044 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
200711 grants / $6,935,927
A Novel Regenerator for Adapting Supercriticial Cycles to Geothermal Power Applications$2,449,000
Funding body: Newcastle Innovation
Funding body | Newcastle Innovation |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor Elham Doroodchi |
Scheme | Administered Research |
Role | Lead |
Funding Start | 2007 |
Funding Finish | 2009 |
GNo | G0189884 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
Development of a Novel Geothermal Power Cycle$2,440,000
Funding body: AusIndustry
Funding body | AusIndustry |
---|---|
Project Team | A/Prof Behdad Moghtaderi |
Scheme | Renewable Energy Development Initiative (REDI) |
Role | Lead |
Funding Start | 2007 |
Funding Finish | 2007 |
GNo | |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | N |
Enhanced Mixing Through Particle Motion in Micro-Channels$427,027
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Laureate Professor Kevin Galvin |
Scheme | Discovery Projects |
Role | Lead |
Funding Start | 2007 |
Funding Finish | 2009 |
GNo | G0186332 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
An Integrated Multi-Node Microfluidics Facility$400,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Professor Geoffrey Evans, Professor Brian Haynes, Professor Assaad Masri, Professor Keith King, Dr Zeyad Alwahabi, Dr Jong-Leng Liow, Assoc. Prof Yinghe He, Laureate Professor Kevin Galvin, Conjoint Professor Bogdan Dlugogorski, Professor Eric Kennedy, Prof LYAZID Djenidi |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) |
Role | Lead |
Funding Start | 2007 |
Funding Finish | 2007 |
GNo | G0186649 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
A Fundamental Study on Redox Behaviour of Oxygen Carriers in Chemical Looping Combustion$365,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Emeritus Professor Terry Wall |
Scheme | Discovery Projects |
Role | Lead |
Funding Start | 2007 |
Funding Finish | 2009 |
GNo | G0186364 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Development of a novel desalination process$250,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Professor Eric Kennedy, Conjoint Professor Bogdan Dlugogorski, Mr Neill Arthur |
Scheme | Linkage Projects |
Role | Lead |
Funding Start | 2007 |
Funding Finish | 2009 |
GNo | G0186607 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Chemical looping : reducing co2 emissions$200,000
Funding body: Newcastle Port Corporation
Funding body | Newcastle Port Corporation |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Emeritus Professor Terry Wall |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2007 |
Funding Finish | 2010 |
GNo | G0187272 |
Type Of Funding | Contract - Aust Non Government |
Category | 3AFC |
UON | Y |
Development of a novel desalination process$161,400
Funding body: Granite Power Pty Ltd
Funding body | Granite Power Pty Ltd |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Professor Eric Kennedy, Conjoint Professor Bogdan Dlugogorski, Mr Neill Arthur |
Scheme | Linkage Projects Partner Funding |
Role | Lead |
Funding Start | 2007 |
Funding Finish | 2009 |
GNo | G0187332 |
Type Of Funding | Grant - Aust Non Government |
Category | 3AFG |
UON | Y |
Dry processing of fine coal using the reflux classifier$130,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Kevin Galvin, Laureate Professor Behdad Moghtaderi |
Scheme | Linkage Projects |
Role | Investigator |
Funding Start | 2007 |
Funding Finish | 2009 |
GNo | G0186610 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Dry processing of fine coal using the reflux classifier$111,000
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Laureate Professor Kevin Galvin, Laureate Professor Behdad Moghtaderi |
Scheme | Linkage Projects Partner Funding |
Role | Investigator |
Funding Start | 2007 |
Funding Finish | 2009 |
GNo | G0187329 |
Type Of Funding | Contract - Aust Non Government |
Category | 3AFC |
UON | Y |
15th European Biomass Conference and Exhibition, International Congress Center, Berlin, Germany, 7/5/2007 - 11/5/2007$2,500
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Travel Grant |
Role | Lead |
Funding Start | 2007 |
Funding Finish | 2007 |
GNo | G0187411 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
20066 grants / $1,137,234
PRC - Priority Research Centre for Energy$549,282
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Conjoint Professor Bogdan Dlugogorski, Laureate Professor Behdad Moghtaderi, Emeritus Professor Robert Antonia, Prof LYAZID Djenidi, Associate Professor Jose De Dona, Professor Eric Kennedy, Associate Professor John Lucas, Conjoint Professor John Mackie, Emeritus Professor Marcel Maeder, Professor Brett Ninness, Emeritus Professor Adrian Page, Associate Professor Marian Radny, Associate Professor Phillip Smith, Professor Edward Szczerbicki, Emeritus Professor Terry Wall |
Scheme | Priority Research Centre |
Role | Investigator |
Funding Start | 2006 |
Funding Finish | 2013 |
GNo | G0186921 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
Smart Utilisation of Thermal Mass in Masonry Buildings$231,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Emeritus Professor Adrian Page, Ms C Inglis |
Scheme | Linkage Projects |
Role | Lead |
Funding Start | 2006 |
Funding Finish | 2008 |
GNo | G0185483 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Smart Utilisation of Thermal Mass in Masonry Buildings$129,000
Funding body: Clay Brick and Paver Institute
Funding body | Clay Brick and Paver Institute |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Emeritus Professor Adrian Page, Ms C Inglis |
Scheme | Linkage Projects Partner Funding |
Role | Lead |
Funding Start | 2006 |
Funding Finish | 2008 |
GNo | G0186727 |
Type Of Funding | Contract - Aust Non Government |
Category | 3AFC |
UON | Y |
Dry classification of fine coal$111,000
Funding body: Australian Coal Association
Funding body | Australian Coal Association |
---|---|
Project Team | Laureate Professor Kevin Galvin, Laureate Professor Behdad Moghtaderi |
Scheme | Research Program |
Role | Investigator |
Funding Start | 2006 |
Funding Finish | 2007 |
GNo | G0186231 |
Type Of Funding | Aust Competitive - Non Commonwealth |
Category | 1NS |
UON | Y |
National Hydrogen Materials Alliance$106,952
Funding body: CSIRO - Commonwealth Scientific and Industrial Research Organisation
Funding body | CSIRO - Commonwealth Scientific and Industrial Research Organisation |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | National Research Flagship Cluster |
Role | Lead |
Funding Start | 2006 |
Funding Finish | 2008 |
GNo | G0185653 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
A Fundamental Study on Microfluidic Characteristics of a Novel Micro-Reactor$10,000
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Prof LYAZID Djenidi |
Scheme | Near Miss Grant |
Role | Lead |
Funding Start | 2006 |
Funding Finish | 2006 |
GNo | G0186070 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
20053 grants / $26,996
Scholarship - Top Up - Semester 2, 2005$14,663
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Multi-Year Project Grant Scholarship |
Role | Lead |
Funding Start | 2005 |
Funding Finish | 2008 |
GNo | G0185739 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
Fluid Dynamic Characterisation of a Novel Micro-reactor for Production of Hydrogen by Partial Oxidation of Methane$9,933
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Project Grant |
Role | Lead |
Funding Start | 2005 |
Funding Finish | 2005 |
GNo | G0184588 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
Fourth Mediterranean Combustion Symposium, 6-10 October 2005$2,400
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Travel Grant |
Role | Lead |
Funding Start | 2005 |
Funding Finish | 2005 |
GNo | G0185758 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
200411 grants / $865,168
Facility for Analysis of Thermal Decomposition of Solid Materials at High Pressures$314,127
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Conjoint Professor Bogdan Dlugogorski, Professor Eric Kennedy, Laureate Professor Behdad Moghtaderi, Emeritus Professor Terry Wall, Professor Scott Donne, Professor Adesoji Adesina, Professor R Burford, Dr A Green, Conjoint Professor John Mackie, Professor Assaad Masri, Assoc. Prof R Creelman, Dr P Wormell, Professor I Thomas |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) |
Role | Investigator |
Funding Start | 2004 |
Funding Finish | 2004 |
GNo | G0183025 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
The Effects of Pyrolysis Conditions on Combustion and Gasification Reactivities of Biomass Chars and the Quality of Their Ash$280,154
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Emeritus Professor Terry Wall, Dr John Stubington |
Scheme | Discovery Projects |
Role | Lead |
Funding Start | 2004 |
Funding Finish | 2006 |
GNo | G0182978 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Facility for Analysis of Thermal Decomposition of Solid Materials at High Pressures$80,000
Funding body: University of Western Sydney
Funding body | University of Western Sydney |
---|---|
Project Team | Conjoint Professor Bogdan Dlugogorski, Professor Eric Kennedy, Laureate Professor Behdad Moghtaderi, Emeritus Professor Terry Wall, Professor Scott Donne |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) Partner Funding |
Role | Investigator |
Funding Start | 2004 |
Funding Finish | 2004 |
GNo | G0183844 |
Type Of Funding | Not Known |
Category | UNKN |
UON | Y |
Experimental Modelling of Masonry buildings Thermal Performance$70,668
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Emeritus Professor Adrian Page, Doctor Heber Sugo, Ms C Inglis |
Scheme | Linkage Projects |
Role | Lead |
Funding Start | 2004 |
Funding Finish | 2006 |
GNo | G0184245 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Facility for analysis of thermal decomposition of solid materials at high pressure$45,000
Funding body: University of New South Wales
Funding body | University of New South Wales |
---|---|
Project Team | Conjoint Professor Bogdan Dlugogorski, Professor Eric Kennedy, Laureate Professor Behdad Moghtaderi, Emeritus Professor Terry Wall, Professor Scott Donne, Professor Adesoji Adesina, Professor R Burford, Dr A Green, Conjoint Professor John Mackie, Professor Assaad Masri, Assoc. Prof R Creelman, Dr P Wormell, Professor I Thomas |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) Partner Funding |
Role | Investigator |
Funding Start | 2004 |
Funding Finish | 2004 |
GNo | G0183842 |
Type Of Funding | Not Known |
Category | UNKN |
UON | Y |
Development of a novel fully-integrated fluidised be (FIFB) reactor for biomass gasification at low temperatures$15,084
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Project Grant |
Role | Lead |
Funding Start | 2004 |
Funding Finish | 2004 |
GNo | G0183423 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
Facility for Analysis of Thermal Decomposition of Solid Materials at High Pressures$15,000
Funding body: University of Sydney
Funding body | University of Sydney |
---|---|
Project Team | Conjoint Professor Bogdan Dlugogorski, Professor Eric Kennedy, Laureate Professor Behdad Moghtaderi, Emeritus Professor Terry Wall, Professor Scott Donne, Professor Adesoji Adesina, Professor R Burford, Dr A Green, Conjoint Professor John Mackie, Professor Assaad Masri, Assoc. Prof R Creelman, Dr P Wormell, Professor I Thomas |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) Partner Funding |
Role | Investigator |
Funding Start | 2004 |
Funding Finish | 2004 |
GNo | G0183843 |
Type Of Funding | Not Known |
Category | UNKN |
UON | Y |
Facility for Analysis of Thermal Decomposition of Solid Materials at High Pressures$15,000
Funding body: University of Technology, Victoria
Funding body | University of Technology, Victoria |
---|---|
Project Team | Conjoint Professor Bogdan Dlugogorski, Professor Eric Kennedy, Laureate Professor Behdad Moghtaderi, Emeritus Professor Terry Wall, Professor Scott Donne |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) Partner Funding |
Role | Investigator |
Funding Start | 2004 |
Funding Finish | 2004 |
GNo | G0183845 |
Type Of Funding | Not Known |
Category | UNKN |
UON | Y |
Experimental Modelling of Masonry buildings Thermal Performance$15,000
Funding body: Clay Brick and Paver Institute
Funding body | Clay Brick and Paver Institute |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Emeritus Professor Adrian Page, Doctor Heber Sugo |
Scheme | Linkage Projects Partner Funding |
Role | Lead |
Funding Start | 2004 |
Funding Finish | 2006 |
GNo | G0184895 |
Type Of Funding | Contract - Aust Non Government |
Category | 3AFC |
UON | Y |
A fundamental study on combustion characteristics of biomass fuels in an O2/CO2 environment$9,427
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Emeritus Professor Terry Wall |
Scheme | Project Grant |
Role | Lead |
Funding Start | 2004 |
Funding Finish | 2004 |
GNo | G0183399 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
Visit of A/Prof M R Rahimour, 31 July 2004 to 15 December 2004$5,708
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Visitor Grant |
Role | Lead |
Funding Start | 2004 |
Funding Finish | 2004 |
GNo | G0183949 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
20035 grants / $337,948
The development of a hybrid energy simulation model for masonry enclosures$240,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Adrian Page, Laureate Professor Behdad Moghtaderi, Doctor Heber Sugo, Ms C Inglis |
Scheme | Linkage Projects |
Role | Investigator |
Funding Start | 2003 |
Funding Finish | 2006 |
GNo | G0182783 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
The development of a hybrid energy simulation model for masonry enclosures$75,000
Funding body: Clay Brick and Paver Institute
Funding body | Clay Brick and Paver Institute |
---|---|
Project Team | Emeritus Professor Adrian Page, Laureate Professor Behdad Moghtaderi, Doctor Heber Sugo |
Scheme | Linkage Projects Partner Funding |
Role | Investigator |
Funding Start | 2003 |
Funding Finish | 2005 |
GNo | G0182784 |
Type Of Funding | Contract - Aust Non Government |
Category | 3AFC |
UON | Y |
Application of Micro Particle Image Velocimetry (Micro-PIV) to Study Thrombus Formation in the Back Gap Region of Centrifugal Blood Pumps$11,340
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Associate Professor George Franks |
Scheme | Project Grant |
Role | Lead |
Funding Start | 2003 |
Funding Finish | 2003 |
GNo | G0182338 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
An experimental study on the structure of gravity currents in a sloping channel$9,208
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Project Grant |
Role | Lead |
Funding Start | 2003 |
Funding Finish | 2003 |
GNo | G0182339 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
Waste Symposium 2003, Cutlers Hall, Sheffield, UK 29 June to 2 July, 2003$2,400
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Travel Grant |
Role | Lead |
Funding Start | 2003 |
Funding Finish | 2003 |
GNo | G0183080 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
200211 grants / $974,558
Fundamental Fire Properties From Extinction and Piloted Ignition Experiments of Solid Fuels$390,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Conjoint Professor Bogdan Dlugogorski, Laureate Professor Behdad Moghtaderi, Conjoint Professor Michael Delichatsios, Professor R Burford |
Scheme | Discovery Projects |
Role | Investigator |
Funding Start | 2002 |
Funding Finish | 2005 |
GNo | G0181064 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Integrated Particle Image Thermometry/Velocimetry Facility.$175,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Professor Geoffrey Evans, Emeritus Professor Graeme Jameson, Conjoint Professor Bogdan Dlugogorski, Emeritus Professor Terry Wall, Professor Dongke Zhang, Assoc. Prof Aibing Yu, Dr H Sidhu, Dr Rodney Weber, Dr Gregory Griffin, Professor Kiet Tieu, Professor Eric Kennedy, Laureate Professor Kevin Galvin, Prof LYAZID Djenidi, Associate Professor Anh Nguyen, Dr Geoffry Mercer |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) |
Role | Lead |
Funding Start | 2002 |
Funding Finish | 2002 |
GNo | G0181517 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
Combined Ozonation-Flotation for the Treatment of Potable Water$152,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Professor Geoffrey Evans, Laureate Professor Behdad Moghtaderi, Professor Simon Biggs, Mr P Dennis |
Scheme | Linkage Projects |
Role | Investigator |
Funding Start | 2002 |
Funding Finish | 2004 |
GNo | G0181147 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Combined Ozonation-Flotation for the Treatment of Potable Water.$105,000
Funding body: Hunter Water Corporation
Funding body | Hunter Water Corporation |
---|---|
Project Team | Professor Geoffrey Evans, Laureate Professor Behdad Moghtaderi, Professor Simon Biggs, Mr P Dennis |
Scheme | Hunter Water Australia Scholarship |
Role | Investigator |
Funding Start | 2002 |
Funding Finish | 2004 |
GNo | G0182553 |
Type Of Funding | Other Public Sector - State |
Category | 2OPS |
UON | Y |
Application of a Novel Reflux Classifier for Separating Nut Shell Fragments from Powdered Food Mixtures$67,635
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Laureate Professor Kevin Galvin, Dr J Ashton |
Scheme | Linkage Projects |
Role | Lead |
Funding Start | 2002 |
Funding Finish | 2004 |
GNo | G0181155 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Combustion Characteristics of Biomass Chars in Pressurised Circulating Fluidised Bed Reactors$40,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Discovery Projects |
Role | Lead |
Funding Start | 2002 |
Funding Finish | 2002 |
GNo | G0181100 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Application of a Novel Reflux Classifier for Separating Nut Shell Fragments from Powdered Food Mixtures.$15,000
Funding body: Sanitarium Health and Wellbeing Company
Funding body | Sanitarium Health and Wellbeing Company |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Laureate Professor Kevin Galvin, Dr J Ashton |
Scheme | Linkage Projects Partner Funding |
Role | Lead |
Funding Start | 2002 |
Funding Finish | 2004 |
GNo | G0182246 |
Type Of Funding | Grant - Aust Non Government |
Category | 3AFG |
UON | Y |
Mathematical Modelling of Oestrogen Effects on Nervous Parasympathetic Control of the Coronary Circulation$14,000
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Conjoint Professor Tony Quail, Laureate Professor Behdad Moghtaderi |
Scheme | Project Grant |
Role | Investigator |
Funding Start | 2002 |
Funding Finish | 2002 |
GNo | G0181392 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
Gas-Solid Fluidisation in Vertical and Inclined Channels.$13,423
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Laureate Professor Kevin Galvin |
Scheme | Project Grant |
Role | Lead |
Funding Start | 2002 |
Funding Finish | 2002 |
GNo | G0181274 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
International Symposium on Fire Safety Science, Massachusetts USA 19-25 May, 2002$2,500
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Travel Grant |
Role | Lead |
Funding Start | 2002 |
Funding Finish | 2002 |
GNo | G0182028 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
INTEGRATED PARTICLE IMAGE THERMOMETRY / VELOCIMETRY FACILITY$0
Funding body: Australian Research Council
Funding body | Australian Research Council |
---|---|
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) |
Role | Investigator |
Funding Start | 2002 |
Funding Finish | 2002 |
GNo | |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | N |
20017 grants / $484,640
High-Speed digital video facility for transient flow analysis.$195,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Professor Geoffrey Evans, Emeritus Professor Graeme Jameson, Laureate Professor Behdad Moghtaderi, Dr Hubert Chanson, Professor Kiet Tieu, Professor Judy Raper, Professor John Reizes, Dr Rose Amal, Associate Professor John Lucas, Dr Tony Howes, Emeritus Professor Robert Antonia, Laureate Professor Kevin Galvin, Professor Simon Biggs, Associate Professor Anh Nguyen, Mr Ian Shepherd |
Scheme | Research Infrastructure Equipment & Facilities (RIEF) |
Role | Investigator |
Funding Start | 2001 |
Funding Finish | 2001 |
GNo | G0179621 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
Thermophysical analysis of the reaction processes at the front end of ironmaking production.$102,314
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Associate Professor John Lucas, Laureate Professor Behdad Moghtaderi, Professor Lazar Strezov |
Scheme | Strategic Partnerships with Industry - Research & Training Scheme (SPIRT) |
Role | Investigator |
Funding Start | 2001 |
Funding Finish | 2002 |
GNo | G0179644 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Thermophysical Analysis of the Reaction Processes at the Front End of Inronmaking Production.$89,450
Funding body: BHP Billiton Research Labs
Funding body | BHP Billiton Research Labs |
---|---|
Project Team | Associate Professor John Lucas, Laureate Professor Behdad Moghtaderi, Professor Lazar Strezov |
Scheme | SPIRT Partner Funding |
Role | Investigator |
Funding Start | 2001 |
Funding Finish | 2002 |
GNo | G0181577 |
Type Of Funding | Contract - Aust Non Government |
Category | 3AFC |
UON | Y |
Gasification Characteristics of Australian Biomass Fuels in Fluidised Bed Reactors.$66,876
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Mr Peter Coombes |
Scheme | Strategic Partnerships with Industry - Research & Training Scheme (SPIRT) |
Role | Lead |
Funding Start | 2001 |
Funding Finish | 2003 |
GNo | G0179629 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Gasification characteristics of Australian biomass fuels in fluidised bed reactors.$15,000
Funding body: Delta Electricity
Funding body | Delta Electricity |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Mr Peter Coombes |
Scheme | SPIRT Partner Funding |
Role | Lead |
Funding Start | 2001 |
Funding Finish | 2003 |
GNo | G0180719 |
Type Of Funding | Contract - Aust Non Government |
Category | 3AFC |
UON | Y |
Soot formation rates from solid polymeric materials for determining their fire hazards in building fires.$11,000
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Project Grant |
Role | Lead |
Funding Start | 2001 |
Funding Finish | 2001 |
GNo | G0180052 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
Production of Hydrogen by Low Temperature Catalytic Steam Gasification of Pine Sawdust in a Fluidised Bed Reactor.$5,000
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi, Conjoint Professor Rajender Gupta |
Scheme | Project Grant |
Role | Lead |
Funding Start | 2001 |
Funding Finish | 2001 |
GNo | G0180049 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
20002 grants / $412,000
Integrated Fire Diagnostics Facility$400,000
Funding body: Department of Education, Training & Youth Affairs
Funding body | Department of Education, Training & Youth Affairs |
---|---|
Project Team | Conjoint Professor Bogdan Dlugogorski, Professor Eric Kennedy, Laureate Professor Behdad Moghtaderi |
Scheme | Research Infrastructure Equipment & Facilities (RIEF) |
Role | Investigator |
Funding Start | 2000 |
Funding Finish | 2000 |
GNo | G0178667 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
A Novel Approach to Study the Re-Ignition Mechanism of Charring Solid Fuels under Fire Conditions.$12,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Small Grant |
Role | Lead |
Funding Start | 2000 |
Funding Finish | 2000 |
GNo | G0178825 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
19991 grants / $92,000
Burnout and Ash Issues Related to Co-Firing of Coal and Biomass in PF Boilers.$92,000
Funding body: CRC for Coal in Sustainable Development
Funding body | CRC for Coal in Sustainable Development |
---|---|
Project Team | Laureate Professor Behdad Moghtaderi |
Scheme | Research Grant |
Role | Lead |
Funding Start | 1999 |
Funding Finish | 1999 |
GNo | G0178995 |
Type Of Funding | CRC - Cooperative Research Centre |
Category | 4CRC |
UON | Y |
Research Supervision
Number of supervisions
Current Supervision
Commenced | Level of Study | Research Title | Program | Supervisor Type |
---|---|---|---|---|
2023 | PhD | Bio-Envelope Instructions to Cater Water for Residents of the Buildings in Different Climate Zones | PhD (Building), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2023 | PhD | Synthesis and Application of Metal-Organic Frameworks for Carbon Dioxide (CO2) Capture | PhD (Chemistry), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2023 | PhD | A Fundamental Investigation of a Novel Two Stage Reduction-Chlorination Process for the Recovery of Precious and Base Metals from Refractory and Difficult to Treat Ores, Tailings and Slags. | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2018 | PhD | A Carbon Arrestor Process: A Novel Approach for the Production of Functional Biochar | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
Past Supervision
Year | Level of Study | Research Title | Program | Supervisor Type |
---|---|---|---|---|
2024 | PhD | Applications of Machine Learning to Predict and Evaluate the Explosion of Premixed Methane- Air Mixtures | PhD (Computer Science), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2023 | PhD | Atmospheric Water Generation Using Desiccant Coated Heat Exchangers | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2022 | PhD | Synthesis, Structure and Application of Coal-derived Few-layer Graphene Composite Materials | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2022 | PhD | A Fundamental Study on Premixed Methane-Air Flame Propagation Dynamics in Straight Long Ducts | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2022 | PhD | Molten Salt Slow Pyrolysis for Advanced Carbon and Renewable Energy | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2022 | PhD | A Fundamental Understanding of Optimal Methods of Contacting Ionic Liquids and Gases at High Flow Rates with a Focus on Capturing Fugitive Methane Emissions from Mining Operations | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2022 | PhD | Study of Catalytic Oxidation of NO in Flue Gas over Mn-Doped Co-Ti-Ox Catalysts | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2022 | PhD | Low-Temperature Catalytic Graphitization of Amorphous Carbon as a Renewable Carbon Material | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2021 | PhD | Freezing of Supercooled Drops of Salt Solutions for Desalination Applications | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2021 | Masters | Promoting the Production of Hydrogen During Steam Pyrolysis of Victorian Brown Coal Using a Pressurized Entrained-Flow Reactor | M Philosophy (Chemical Eng), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2021 | PhD | Chemical Looping Based Utility-Scale Energy Storage | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2021 | PhD | The Assessment of the Thermal Performance of Various Walling Systems and Complete Houses Using the Dynamic Temperature Response Concept | PhD (Civil Eng), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2021 | PhD | Assessment of a Novel Concept for Co-generation of Heat and Power | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2021 | PhD | Ultrasonic-Assisted Freezing of Micro-sized Water Droplets | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2021 | PhD | A Mechanistic Study of the Structural Transformations in Australian Coking Coals and Blends Across the Plastic Layer During Coking | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2020 | PhD | Ignition and Explosion Characteristics of Coal Dust and Methane Mixture Under Conditions Pertinent to Ventilation Air Methane Abatement | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2020 | PhD | First-Principles Investigation of Trends in High-Temperature Thermochemistry of Perovskite Oxides | PhD (Chemistry), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2019 | PhD | Empirical and Theoretical Modelling of the Effects of Slab-Edge-Insulation in Slab-on-Ground Housing | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2018 | PhD | Low-Carbon and Affordable Retrofits of Australian Housing for Climate Change and Scarce Resource Scenarios | PhD (Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2018 | PhD | Advanced Applications of Tunable Magnetite Nanofluids in Energy Systems and Energy Harvesters | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2017 | PhD | Application of Calcium Looping for Heat Generation and CO2 Enrichment in Greenhouses | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2017 | PhD | A Novel Ex-Situ Calcium Looping Process for Removal and Conversion of Tars Formed During Biomass Gasification | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2016 | PhD | A Fundamental Study on Char Creation from Coal Tailings ('Chailings') and Its Application as a Soil Amendment | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2016 | PhD | Transport Characteristics of Binary Mixture of Particles in Chemical Looping Combustion Applications | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2016 | PhD | Formation of Toxic Compounds in the Thermal Decomposition of 1,3-Dichloropropene | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2016 | PhD | Thermal Studies of Chlorinated Thiophenols | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2016 | PhD | A Fundamental Study on Membrane Integrated Chemical Looping Air Separation Process | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2016 | Masters | An Analysis of the Impacts of Biochar to Disturbed Soils from the Hunter Valley, New South Wales | M Philosophy (EnvironmentalSc), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2016 | PhD | The Development of a Comprehensive Metric Which Characterises the Thermal Performance of Complete Buildings | PhD (Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2015 | PhD | Reactions, Transformations and Impacts of Sulphur Oxides During Oxy-fuel Combustion | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2015 | PhD | Gas Quality Control in Oxy-Fuel Technology for Carbon Capture and Storage: Scrubbing of C02 Prior to Compression | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2015 | PhD | The Removal of Nitrogen Oxides and Mercury as Condensates During the Compression of Oxyfuel Flue Gas | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2015 | PhD | Chemical Looping Air Separation for Oxy-fuel Power Plants | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2014 | PhD | A Fundamental Study on Hybrid Geothermal Energy Systems | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2014 | PhD | Laboratory Evaluation of Combustibility of Coals for Blast Furnace Pulverised Coal Injection | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2014 | PhD | Utilisation of Ventilation Air Methane in Chemical Looping Systems | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2013 | PhD | Application of Supercritical Carbon Dioxide in Engineered Geothermal System | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2013 | PhD | A Fundamental Study on Heat Transfer Characteristics of Magnetite Nanofluids | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2012 | PhD | Pulverised Coal Combustibility in Simulated Oxyfuel (O2/CO2) and Air (O2/N2) Conditions | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2011 | Masters | Dewatering of Wastewater Sludge | M Engineering (Chemical) [R], College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2011 | PhD | Ignition Behaviour of Individual Pulverized Coal Particles in Air and Oxy-fuel Environments | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2011 | Masters | High Fidelity Simulation of Future Low Emissions Stationary Electricity Generation Scenarios | M Philosophy (Chemical Eng), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2010 | PhD | Microwave Characterisation of Typical Australian Wood-Based Biomass Materials | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2010 | PhD | Smart Utilisation of Thermal Mass in Masonry Buildings | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2010 | PhD | Neuro-Fuzzy Modelling of the Thermal Performance of Typical Australian Residential Buildings | PhD (Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2010 | PhD | Flame Spread Over Inert Porous Solids Wetted with Flammable Liquids Under Conditions Pertinent to Industrial Fires | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2008 | PhD | Heat Transfer in Air-Fired Pulverised Fuel Furnaces Retrofitted to Oxy-Fuel Coal | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2006 | Masters | A Thermodynamic Equilibrium Approach for Assessing Slagging and Fouling Potentials of Biomass During Combustion | M Engineering (Chemical) [R], College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2006 | PhD | The Influence of Parallel Plates on Elutriation of Fine Particles from a Gas-Solid Fluidised Bed | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2006 | PhD | A Fundamental Study on Pilot-Scale Characteristics of Coal and Biomass Blends for Co-Firing Applications | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2005 | PhD | A Fundamental Study on the Gasification Kinetics of Biomass Chars | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2005 | PhD | A Fundamental Study on Re-ignition Characteristics of Wood-Based Materials | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2003 | PhD | A Fundamental Study on Combustion Characteristics of Pulverised Coal/Softwood Blends | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2000 | PhD | Sintering of Ash from Black Coal in Pressurised Fluidised Bed Combustion Systems | Chemical Engineering, University of Newcastle | Principal Supervisor |
Research Collaborations
The map is a representation of a researchers co-authorship with collaborators across the globe. The map displays the number of publications against a country, where there is at least one co-author based in that country. Data is sourced from the University of Newcastle research publication management system (NURO) and may not fully represent the authors complete body of work.
Country | Count of Publications | |
---|---|---|
Australia | 294 | |
China | 22 | |
Jordan | 16 | |
Iran, Islamic Republic of | 10 | |
United States | 10 | |
More... |
News
News • 6 Mar 2024
Inaugural Showcase debuts cutting-edge solar and hydrogen technologies
More than 200 industry, government officials, researchers, start-ups and university staff came together yesterday to celebrate the achievements of the Trailblazer for Recycling and Clean Energy (TRaCE) program.
News • 18 Jan 2024
University of Newcastle renewable energy storage research gains international buzz
The University of Newcastle's renewable energy expertise is being broadcast to over 60 million people around the world as part of a new documentary series presented by American actor Dennis Quaid.
News • 31 Aug 2023
Partnership to help heavy industries reach net zero emissions with carbon capture technology begins
A project to bring a revolutionary carbon capture technology to market with the potential to help heavy industries reach net zero by 2030 has kicked off with a $6 million research partnership between the University of Newcastle and ASCON Group.
News • 9 May 2023
Partnership puts Green Ammonia project on fast track for real world use
A cleaner greener future is one step closer thanks to a new $18 million research partnership between the University of Newcastle and Australian company Element One, and the Australian Government.
News • 18 Mar 2022
Future Drought Fund win for 'Hydro Harvester'
Laureate Professor Behdad Moghtedari and his team have secured $1.75 million from the Australian Government’s Future Drought Fund to scale-up the Hydro Harvester technology.
News • 7 Apr 2021
Green hydrogen demonstration drives zero emission future
A state-of-the-art green hydrogen fuel, developed in partnership between the University of Newcastle and Southern Green Gas has today been unveiled and demonstrated in Hyundai’s NEXO hydrogen fuel cell SUV.
News • 4 Sep 2020
New green hydrogen made from solar power and air
In a remarkable first, a system that combines solar energy with water harvested from air has been used to manufacture low cost green hydrogen – a zero-emissions fuel.
News • 31 Jan 2020
Local researchers succeed in latest ARC Linkage funding
Two University of Newcastle researchers, and a research team have been awarded more than $1.7 million from the Australian Research Council (ARC) for projects that support advancements in sustainable energy, health, agriculture and mineral processing.
News • 11 Dec 2019
Hydro Harvester is making a splash to solve global water shortage
In what could be a game-changer for solving the world’s water shortage problem, an atmospheric water generator (AWG) developed at the University of Newcastle is one step closer to commercialisation.
News • 3 Oct 2019
More than $1.4million awarded to investigate PFAS remediation
The University of Newcastle has established itself as leader in PFAS remediation research, receiving more than $1.4 million in Australian Research Council (ARC) funding for two of the four national research projects selected in Round Two of the PFAS Remediation Research Program.
News • 3 Oct 2018
Excellence in chemical engineering solutions
Professor Behdad Moghtaderi has been recognised for the application of ingenuity and technical knowledge in developing practical solutions to industry problems or opportunities; receiving the prestigious ExxonMobil Award of Excellence in Chemical Engineering.
News • 22 Aug 2018
‘Water from thin air’ recognised for industry innovation
Professor Behdad Moghtaderi has been recognised for innovation in the water industry, receiving a Hunter Water Night of Innovation Gala award for his ‘water from thin air’ project.
News • 2 Aug 2018
Professor Moghtaderi receives national engineering award
The University of Newcastle’s Professor Behdad Moghtaderi has been awarded an Australian Engineering Excellence Award for the development of the world’s first large scale testing facility for ventilation air methane abatement.
News • 17 May 2018
Professor Moghtaderi wins an Australian Good Design Award for the world’s first VAM abatement testing facility
Professor Behdad Moghtaderi has been awarded a prestigious Good Design Award in the Engineering Design category for the world’s first large-scale testing facility for assessment of ventilation air methane (VAM) abatement systems.
News • 23 Mar 2018
Australia one step closer to solving global water challenge
Pioneering research team Hydro Harvest Operation from the University of Newcastle (UON) have today been announced as the only Australian team to reach the finals of a worldwide XPRIZE competition, set to solve the planet’s global water shortage crisis.
News • 25 Oct 2017
Emissions reduction technology enters new phase
The University of Newcastle (UON) has unveiled a world-first, $10.5 million demonstration facility to carry out controlled testing of an abatement technology that captures fugitive methane emissions from underground coal mining operations.
News • 22 Sep 2016
NIER engineering project awarded for excellence
The Newcastle Institute for Energy and Resources (NIER) received accolades at the Engineers Australia Excellence Awards on Friday September 16.
News • 8 Sep 2016
$4.2 million research centre for sustainable clean energy technologies
News • 28 Aug 2015
Sustainable energy research powers developing world
A breakthrough sustainable energy technology at the University of Newcastle (UON) could help solve the global challenge of rural electrification in developing countries.
News • 1 Jun 2015
Clean energy technology scoops excellence pool
A UON revolutionary clean energy technology scooped the pool at the 2015 Newcastle Engineering Excellence Awards.
News • 21 Oct 2014
Excellence in Science and Engineering awarded
Two University of Newcastle academics have been honoured with prestigious accolades at the 2014 NSW Science and Engineering Awards.
News • 15 Apr 2014
Revolutionary clean energy technology launched in the Hunter
A new clean energy system launched today will demonstrate cost savings in electricity generation for remote mining and industrial sites and rural communities.
News • 20 Feb 2014
World First Emissions Abatement Technology
The University of Newcastle has received $30 million to develop and roll-out world-leading abatement technologies for fugitive methane emissions from underground coal mining operations. The new technologies could reduce these emissions from the sector by as much as 90 percent and reduce Australia's annual greenhouse gas output by three percent.
Laureate Professor Behdad Moghtaderi
Position
Laureate Professor
School of Engineering
College of Engineering, Science and Environment
Focus area
Chemical Engineering
Contact Details
behdad.moghtaderi@newcastle.edu.au | |
Phone | (02) 40339062 |
Mobile | 0418408615 |
Fax | (02) 40339095 |
Office
Room | A214 |
---|---|
Building | A-Blk; N'cle Institute for Energy & Res (NIER) Precinct |
Location | Callaghan University Drive Callaghan, NSW 2308 Australia |