Emeritus Professor Graeme Jameson
Emeritus Professor
School of Engineering (Chemical Engineering)
- Email:graeme.jameson@newcastle.edu.au
- Phone:(02) 4921 6181
A revolution in mining and engineering
Laureate Professor Graeme Jameson is a globally renowned researcher in the field of mineral processing and the acclaimed inventor of the Jameson Cell, a froth flotation device that has delivered big wins for the environment and is considered Australia’s biggest-earning innovation for the past quarter century.
Laureate Professor Graeme Jameson’s work has revolutionised the way valuable minerals, the bedrock of the Australian economy, are extracted from rocks. His most famous invention, the Jameson Cell, has netted Australia roughly $51 billion in exports.
Named after its inventor, the Jameson Cell has also led to significant savings in Australia’s energy consumption and reductions in greenhouse gas emissions — and earned Graeme almost legendary status in mining and engineering circles.
Graeme is now working to bring his latest award-winning invention, the NovaCell, to commercial reality.
Graeme’s remarkable achievements and enduring reputation as a prominent global expert attract high numbers of talented engineering students, researchers and academics to the University of Newcastle every year.
A billion-dollar idea
The Jameson Cell is an ingenious flotation device that changed the way minerals could be recovered. It has become a global industry gold standard and is now featured in undergraduate textbooks for aspiring engineers worldwide.
The process involves grinding mineral ores into small particles, suspending them in water and placing them into stirred tanks known as cells. The Jameson Cell blows air bubbles up through the liquid and uses reagents to make mineral particles stick to them. The bubbles form a mineral-rich froth on the surface, which is then scraped off.
A large mine can treat 10,000 tonnes an hour — that's similar to 10,000 small cars being reduced to dust every hour.
"I had been looking at ways to improve the flotation process for many years. I knew flotation was important to the Australian industry and felt the answer lay in the mechanics of fluids and particles,” explains Graeme.
The technology was developed for commercial application in partnership with Mount Isa Mines Limited, who Graeme says, “quickly identified the cell’s potential”.
These days, there are more than 300 Jameson Cells in operation across 25 countries, being used for copper, coal, zinc, nickel, lead, silver and platinum extraction worldwide.
The Cell has also been used for environmental applications, including extracting oil from tar sands in Canada, cleaning up industrial wastewaters in Newcastle and other locations in Australia, and removing blue-green algae from waterways in inland Australia.
The finely-ground particles that were once too small to recover and previously were dumped into rivers, or buried, can now be processed. Old mines now have a longer life, and the environmental damage caused by the need to open more new mines is reduced.
The NovaCell
Graeme now has his sights set on an exciting invention which he calls the NovaCell: a radical way of recovering coarse mineral particles as large as beach sand. The NovaCell uses a fluidised bed to collect coarse particles and a high shear aeration zone for ultra-fines separation.
Graeme likens his new technology to the landscape that Newcastle is famous for — the beach.
"Imagine a bed of sand. If you're well away from the water the sand will be pretty stable and if you stand on it, you don't sink. However, if you go a bit closer to the water you can make the sand fluidise just by moving your feet up and down.”
"The sand stays more or less in the same place but the water in the sand is pumped up and down and momentarily it lifts particles away from their neighbours, so the sand becomes liquid-like and you can sink down into it.
"The fluidised bed flotation device uses the same principles by pushing air bubbles through the sediment and this creates a quiet environment for the larger particles to attach to the bubbles."
Simply put, the Cell could eliminate the need to grind ore very finely, resulting in big savings — both financially, and for the environment through a reduction in greenhouse gas emissions, and energy and water consumption. The device shows a 40% reduction in comminution energy and a 10% reduction in overall site operating costs.
The NovaCell has already generated a buzz within the industry, and secured Graeme the prestigious 2019 CEEC Medal for Technical Research alongside his Research Associate Dr Cagri Emer.
Challenges of time and money
Graeme knows only too well how difficult it can be to take a fledging idea and turn it into a commercially viable product. Research oriented towards solving industrial problems takes a good deal of time, determination, and funding.
“Solutions can take a long time to bring to fruition. If one fails to solve a problem, the problem does not go away and you can’t pivot your research in another direction, you have to keep going.”
“But the biggest barrier is what is known as The Gap. This refers to the funding of the intermediate stage of commercial development.
“Once a prototype has been developed and tested, it is not so difficult to find an industrial partner to take up the idea. However, the inventor must find the costs for the prototype, and the funding for this step is very difficult to find.”
Creating a legacy
Graeme has clocked up countless achievements over his impressive career.
He received an Order of Australia Medal, AO, in 2005, the Antoine M. Gaudin Medal in 2013, the inaugural Prime Minister's Prize for Innovation in 2015 and the Peter Nicol Russell Memorial Medal from the Institution of Engineers Australia for outstanding service to his profession.
In 2018, Graeme was elected to the world’s oldest and highly prestigious scientific society, the Royal Society of London. The Society’s wall of fame includes names such as Newton, Darwin, Hawking and Einstein. Graeme describes the election as, “the most rewarding moment in my career”.
Ever humble despite his growing list of accolades and accomplishments, Graeme’s work is
underscored by his unyielding commitment to producing real-world solutions and creating a lasting legacy for communities and our nation.
"I see science and technology as agents for improving people's lives. I believe that if you're going to put your heart into something, you may as well tackle a problem that will make a difference and benefit the community.”
With a number of prospects still emerging from his latest research, Graeme continues to be a gold mine of innovation for Australian industry.
A revolution in mining and engineering
Laureate Professor Graeme Jameson is a globally renowned researcher in the field of mineral processing and the acclaimed inventor of the environmentally friendly Jameson Cell, a froth flotation device that is Australia’s biggest-earning innovation for the past quarter century.
A gold mine of innovation
Laureate Professor Graeme Jameson's contribution to the Australian economy and the environment as the inventor of what is considered by many to be the nation's biggest export earner in the last 25 years, has earned him gold status within the minerals industry and the inaugural Prime Minister's Prize for Innovation in 2015.
Dealing in 'bubbles', Prof Jameson revolutionised a mineral separation process first invented in 1905, to develop the Jameson Cell, a froth flotation device, that has netted Australia more than $36 billion in exports.
Prof Jameson' research continues to push the boundaries and he is currently working on a Fluidised Bed Flotation Cell that has the potential to make massive reductions in the energy used in Australia's minerals industry.
The invention
For many years, Prof Jameson's attention had been focused on improving the effectiveness of extracting valuable minerals from rock.
"I had been looking at ways to improve the flotation process for many years. I knew flotation was important to the Australian industry and felt the answer lay in the mechanics of fluids and particles," Prof Jameson said.
The Jameson Cell is a radically different flotation device that changed the way that minerals were recovered and earned Jameson almost legendary status in mining and engineering circles.
With over 300 cells now in operation across 25 countries, the Cell is being used for copper, coal, zinc, nickel, lead, silver and platinum extraction world-wide.
The process involves grinding mineral ores into small particles, suspending them in water and placing them into stirred tanks known as cells. A large mine can treat 10,000 tonnes an hour – that's similar to 10,000 small cars being reduced to dust every hour.
The Cell works by blowing air bubbles up through the liquid and using reagents to make mineral particles stick to them. The bubbles form a mineral-rich froth on the surface, which is then scraped off.
Saving the environment
As well as recovering billions of dollars' worth of fine coal and minerals a year, the Cell has also been used for industrial and environmental applications including extracting oil from tar sands in Canada, cleaning up industrial wastewaters in Newcastle and other locations in Australia, and removing blue-green algae from waterways in inland Australia.
The finely-ground particles that were once too small to recover and previously were dumped into rivers, or buried, can now be processed. Old mines now have a longer life, and the environmental damage caused by the need open more new mines is reduced.
A core commitment
Jameson's reputation for commitment to an issue was formed early in his career and cemented during his early years at the University of New South Wales.
There he worked as a chemical engineering cadet in Sydney while studying part-time over an eight year period, saving to pay his living expenses to do a PhD at Cambridge University. He arrived at the University of Newcastle as Professor of Chemical Engineering in 1978.
"I see science and technology as agents for improving people's lives. I'm strongly of the view that curiosity-driven research is of great benefit to society, particularly when it is linked, however tenuously, with the solution of a real practical problem," Prof Jameson said.
"As an engineer, my interest is in striving to fix problems that are important to a particular industry, and have previously proven difficult to solve. I like to identify a problem, do the fundamental research into why the current technologies aren't working, and then come up with a practical solution based on the research," he said.
Jameson is held in high esteem by colleagues and researchers in the field of flotation. The Editor of Minerals Engineering, Dr Barry Wills, describes Prof Jameson as a "top class scientist and pioneer in flotation science and practice".
Prof Jameson's services to engineering, science, industry and the environment were recognised when he was awarded an Order of Australia Medal, AO, in 2005. He also was awarded the world's most prestigious award in mineral processing, the Antoine M. Gaudin Medal, in 2013.
Other accolades include the CSIRO Medal and being recognised as a Fellow of the Australian Academy of Sciences, the Royal Academy of Engineering in the UK and the Australian Academy of Technological Sciences.
In the true mark of a scientist, 30 years on from his initial breakthrough discovery, Prof Jameson is still fine-tuning and improving the Jameson Cell.
"I believe that if you're going to put your heart into something, you may as well tackle a problem that will make a difference and benefit the community.
Floating big ideas
At this point in his life, he is not ready to hang up the lab coat. He is now aiming to bring his latest invention, the Fluidised Bed Flotation Cell, to commercial reality. The device will increase the upper particle size limit of flotation and drastically reduce the mining industry's energy and water consumption.
Jameson said he wants to create a "quiet environment' for flotation which, interestingly, seems to be in keeping with his softly-spoken character.
It has been estimated by the CSIRO that the energy used in grinding rock to retrieve valuable material is equal to 14 per cent of Australia's electricity production.
"In this day and age, the amount of valuable material recovered is very small, representing one to two per cent of the feed material, so we are grinding 98 per cent of the feed, only to throw it away," Prof Jameson said.
"To recover particles of copper ore, for example, it is necessary to grind the whole of the feed to the plant, to a top size that is typically 150µm - about the size of a human hair," he said.
"Currently, because the coarse particles are knocked off the bubbles by the violent, turbulent action in the tank, there is a need to grind the particles to a super-fine state.
"My theory is that if we can extract these coarse particles, you won't have to grind so fine and you won't have to expend so much energy."
Jameson likens his new technology to the landscape that Newcastle is famous for - the beach.
"Imagine a bed of sand. If you're well away from the water the sand will be pretty stable and if you stand on it, you don't sink. However, if you go a bit closer to the water you can make the sand fluidise just by moving your feet up and down," he said.
"The sand stays more or less in the same place but the water in the sand is pumped up and down and momentarily it lifts particles away from their neighbours, so the sand becomes liquid-like and you can sink down into it.
"The fluidised bed flotation device uses the same principles by pushing air bubbles through the sediment and this creates a quiet environment for the larger particles to attach to the bubbles."
Prof Jameson recently completed a study that showed that the costs associated with a mine were roughly 43 per cent mining, 43 per cent milling and concentration and 14 per cent general administration. So a significant reduction in the milling costs will have a flow-on effect for the whole mining enterprise.
The Fluidised Bed Flotation Cell is estimated to potentially cut total operating costs of a mining venture, including the mine and the concentrator, by 10 to 20 per cent.
Prof Jameson's next milestone will be to develop an operational pilot plant that can be taken to a mine site for testing.
With a number of prospects still emerging from his latest research, Prof Jameson continues to be a gold mine of innovation for Australian industry.
Watch an interview with Graeme Jameson on 2NUR FM radio station
A gold mine of innovation
Laureate Professor Graeme Jameson's contribution to the Australian economy and the environment as the inventor of what is considered by many to be the nation's biggest export earner in the last 25 years, has earned him gold status within the…
Legacy of leadership
The University's strength in engineering owes much to the work ethic and reputation of its trailblazers.
One need look no further than the University of Newcastle's Centre for Advanced Particle Processing and Transport for proof of the adage 'success breeds success'.
The Centre is renowned for world-leading research into the processing, storage and transport of minerals and industrial products and boasts an outstanding record of commercial and academic achievement. Its research has led to technological advances that have produced multi-million dollar savings for industry, and it is at the forefront of developing new-generation processes that reduce water and energy use.
Much of that success is due to the foundation laid by two of the University's elder statesmen and principal researchers in engineering, Laureate Professor Graeme Jameson and Emeritus Professor Alan Roberts.
Both have had long and esteemed careers with the University, Roberts arriving as Professor of Industrial Engineering in 1974 and Jameson as Professor of Chemical Engineering in 1977.
Both have been recognised with Order of Australia awards and have received the prestigious Peter Nicol Russell Memorial Medal from the Institution of Engineers Australia for outstanding service to their profession. Both have also been elected to learned scientific and engineering academies.
Roberts was responsible for the University developing what has become an important and lucrative niche in bulk materials handling, a little-explored area of research back in the 1970s.
He established TUNRA Bulk Solids Handling as a research group and commercial consultancy in 1975. Since then it has completed more than 4000 projects for clients in 40 countries and made an invaluable contribution to research in the field.
"It has become one of the flagships of the University and has certainly validated the decision to go down that path," says Roberts, who is officially retired but still works from his office at the University's Newcastle Institute for Energy Resources (NIER) most days.
"Our work has spanned everything from fine pharmaceutical powders, to plastic powders, agricultural grains, domestic waste and minerals such as iron ore, bauxite and coal. Bulk solids handling is a complex aspect of the industrial process that applies to anything that is transported in powdered or granular form."
Jameson was already a respected expert in fluid mechanics when he came to prominence in the 1980s with his invention of the Jameson Cell. A froth flotation device for recovering fine mineral particles from mine waste and low-yield sources, it was smaller, faster and more precise than existing technology and was quickly taken up by industry.
These days there are more than 300 Jameson Cells in operation in 21 countries around the world. As well as recovering billions of dollars worth of fine coal and minerals a year, they are being put to new industrial applications including extracting oil from tar sands in Canada and removing blue-green algae from waterways in central Australia.
"It was one of those 'Eureka!' moments when all the work you have done beforehand comes together in one realisation," Jameson says of the moment he conceived the Cell.
"I was with some students at a mine in Mount Isa and I looked at the equipment they were using and thought, 'I could build something better than that'."
In their early years at the University, both Jameson and Roberts were committed to lifting the research profile of the engineering group, along with another long-time departmental leader Professor Terry Wall.
Their establishment of research centres in multiphase processing, bulk solids handling and black coal utilisation was important both in facilitating the expansion of research and enhancing the status of the University as a leader in those fields.
The University has long been a magnet for talented engineering students, researchers and academics and this is due in no small part to the reputations of Jameson and Roberts.
Find out more
Legacy of leadership
Laureate Professor Graeme Jameson is a world renowned researcher creating the heralded Jameson cell.
Career Summary
Biography
- Chemical Engineering
Qualifications
- PhD, University of Cambridge - UK
- Associate of Sydney Technical College, Sydney Technical College
- Bachelor of Science (Honours)(Chem Engineering), University of New South Wales
Keywords
- Fluid Mechanics
- Mineral Processing
- Surface Chemistry
- chemical engineering
Fields of Research
Code | Description | Percentage |
---|---|---|
401904 | Mineral processing/beneficiation | 60 |
400409 | Separation technologies | 40 |
Professional Experience
Academic appointment
Dates | Title | Organisation / Department |
---|---|---|
Fellow - Royal Australian Chemical Institute | Royal Australian Chemical Institute Australia |
|
Honorary Fellow - Institution of Engineers, Australia | Institution of Engineers, Australia (IEAus) Australia |
|
1/5/2000 - 1/5/2004 | Chair - Selection Committee 5 (Engineering & Applied Science) | Australian Academy of Science |
1/1/1975 - | Fellow - Institution of Chemical Engineers | Institution of Chemical Engineers (IChemE) United Kingdom |
1/8/1965 - 1/8/1978 | Reader in Chemical Engineering of the University of London | Imperial College of Science & Technology, London Department of Chemical Engineering and Chemical Technology United Kingdom |
Membership
Dates | Title | Organisation / Department |
---|---|---|
Member - Society for Mining, Metallurgy and Exploration (SME) US | Society for Mining, Metallurgy and Exploration (SME) United States |
|
8/5/2018 - | Fellow of the Royal Society of London | The Royal Society United Kingdom |
6/9/2016 - | Lifetime Achievement Award 2016 | International Mineral Processing Council Canada |
6/9/2015 - | Prime Minister's Science Prize for Innovation 2015 | Department of Prime Minister and Cabinet Australia |
1/9/2015 - | Foreign Member, US National Academy of Engineering | National Academy of Engineering United States |
6/9/2013 - | New South Wales Scientist of the Year 2013 | NSW Department of Premier and Cabinet Australia |
6/2/2013 - | Antoine Gaudin Award 2013 | Society of Mining Engineers, Mining and Mineral Processing Division United States |
6/1/2005 - | Officer of the Order of Australia | Order of Australia Australia |
6/1/2003 - | Ian Wark Medal and Lecture | Australian Academy of Science |
6/6/1998 - | K L Sutherland Memorial Medal | ATSE (Australian Academy of Technology and Engineering) |
1/1/1996 - | Fellow - Australian Academy of Science | Australian Academy of Science |
1/7/1994 - | Foreign Fellow- Royal Academy of Engineering (UK) | Royal Academy of Engineering United Kingdom |
1/1/1992 - 31/12/1994 | Committee Member and Chair - ARC | ARC Engineering Panel Australia |
1/1/1991 - | Fellow - Australian Academy of Technological Sciences and Engineering | ATSE (Australian Academy of Technology and Engineering) |
1/1/1990 - | Fellow - Australasian Institute of Mining and Metallurgy | Australasian Institute of Mining and Metallurgy Australia |
Professional appointment
Dates | Title | Organisation / Department |
---|---|---|
1/1/2014 - 31/12/2016 | ARC Outstanding Researcher Award (DORA Fellowship) | ARC (Australian Research Council) |
Awards
Distinction
Year | Award |
---|---|
2016 |
Lifetime Achievement Award International Mineral Processing Council |
2013 |
Guillaume Delprat Distinguished Lecturer Australasian Institute of Mining and Metallurgy |
2013 |
Antoine Gaudin Award Society for Mining, Metallurgy and Exploration (SME) |
2013 |
NSW Scientist of the Year Office of the NSW Chief Scientist and Engineer |
2004 |
Laureate Professor University of Newcastle |
Honours
Year | Award |
---|---|
2015 |
Foreign Member, US National Academy of Engineering US National Academy of Engineering |
2005 |
Order of Australia in the class of Officer (AO) Council for the Order of Australia |
2003 |
Sir Ian Wark Medal and Lecture Australian Academy of Science |
2002 |
Centenary Medal Commonwealth |
1996 |
Fellow Australian Academy of Science |
1994 |
Foreign Fellow Royal Academy of Engineering |
1991 |
Fellow ATSE (Australian Academy of Technology and Engineering) |
Prize
Year | Award |
---|---|
2015 |
Prime Minister's Science Prize for Innovation Commonwealth Department of Industry Science and Technology |
Recognition
Year | Award |
---|---|
2014 |
Membership - International Mining Technology Hall of Fame International Mining Technology Hall of Fame |
2005 |
Peter Nicol Russell Medal Institution of Engineers Australia (IEAust) |
1999 |
President's Medal Australasian Institute of Mining and Metallurgy |
1998 |
K L Sutherland Memorial Medal ATSE (Australian Academy of Technology and Engineering) |
1993 |
R K Murphy Medal Royal Australian Chemical Institute |
1991 |
Clunies Ross National Science and Technology Award ATSE (Australian Academy of Technology and Engineering) |
1990 |
CSIRO External Research Medal Commonwealth Scientific and Industrial Research Organisation (CSIRO) |
Invitations
Participant
Year | Title / Rationale |
---|---|
2006 |
Bubbles in Food Organisation: University of Manchester Description: Gave the keynote address on Bubbles and Foams in Food. |
PhD Examiner
Year | Title / Rationale |
---|---|
2006 |
PhD thesis Organisation: Various Description: In the review period I have reviewed theses from University of Queensland, Sydney, Cape Town |
Publications
For publications that are currently unpublished or in-press, details are shown in italics.
Book (1 outputs)
Year | Citation | Altmetrics | Link |
---|---|---|---|
2007 | Fuerstenau MC, Jameson GJ, Yoon R-H, Froth Flotation; A Century of Innovation, Society for Mining, Metallurgy, and Exploration, Littleton, CO, 891 (2007) [A3] |
Chapter (8 outputs)
Year | Citation | Altmetrics | Link | ||
---|---|---|---|---|---|
2014 |
Jameson GJ, 'Jameson Cell Technology for Organics Recovery', Oil Spill Remediation: Colloid Chemistry-Based Principles and Solutions 221-229 (2014) [B1] The separation and recovery of oil that has spilled in the sea poses a number of problems. The first is to capture the oil/water mixture with the minimum amount of clean sea water... [more] The separation and recovery of oil that has spilled in the sea poses a number of problems. The first is to capture the oil/water mixture with the minimum amount of clean sea water. Once this has been done, further problems arise, such as the need to separate the oil from the aqueous medium, in large volumes, at high efficiencies and at an economic cost. Solutions to such problems have been found, and are already in operation in the resource and energy industries. The flotation process, which was initially developed to separate valuable mineral particles from waste material, has been successfully applied to the separation of organics. The Jameson Cell is a specific technology that has found widespread application for the recovery of organics during solvent extraction - electrowinning (SX-EW), and is now being used for recovery of bitumen in the processing of oil sands. The largest single cell in operation can handle 3,000m3/hr (792,000 US gallons/hr), and can readily be adapted to the treatment of oil spill separations. Here, the mechanics of the Jameson Cell are explained, and operational data presented.
|
Nova | |||
2007 |
Jameson GJ, Nguyen AV, Ata S, 'The flotation of fine and coarse particles', Froth Flotation: A Century of Innovation, Society for Mining, Metallurgy, and Exploration, Englewood, Colorado 339-372 (2007) [B1]
|
||||
2006 |
Nguyen AV, Pugh RJ, Jameson GJ, 'Collection and Attachment of Particles by Air Bubbles in Froth Flotation', Colloidal Particles at Liquid Interfaces, Cambridge University Press, Cambridge 328-382 (2006) [B1]
|
||||
2006 |
Nguyen AV, Evans GM, Jameson GJ, 'Electrical Double-Layer Interaction between Spherical Particles: Appoximate Expressions', Encyclopedia of Surface and Colloid Science, Taylor & Francis, London 1971-1981 (2006) [B1]
|
||||
2005 |
Nguyen AV, Phan MC, Evans GM, Jameson GJ, 'Dynamic Adsorption of Surfactants at the Gas-Liquid Interface', Innovations in Natural Resource Processing, Society for Mining, Metallurgy, and Exploration, Englewood, Colorado 87-98 (2005) [B1]
|
Nova | |||
2002 |
Nguyen AV, Evans GM, Jameson GJ, 'Approximate expressions for electrical double-layer interaction between spherical particles', Encyclopedia of Surface and Colloid Science, Marcel Dekker Inc., USA 630-641 (2002) [B2]
|
||||
2000 | Jameson GJ, 'Flotation', Encyclopedia of Separation Science, Academic Press, London, U.K. 700-710 (2000) [B1] | ||||
1999 | Magrabi SA, Dlugogorski BZ, Jameson GJ, 'Ostwald ripening in aqueous foams', Foams and Films, Verlag MIT Bremen, Bremen, Germany 87-95 (1999) [B1] | ||||
Show 5 more chapters |
Journal article (169 outputs)
Year | Citation | Altmetrics | Link | ||||||||
---|---|---|---|---|---|---|---|---|---|---|---|
2022 |
Hoque MM, Doroodchi E, Jameson GJ, Evans GM, Mitra S, 'Numerical estimation of critical local energy dissipation rate for particle detachment from a bubble-particle aggregate captured within a confined vortex', Minerals Engineering, 180 (2022) [C1] In flotation, interactions of bubble-particle aggregates with turbulent flow structures in the liquid medium result in particle detachment. This study aims to simulate this phenom... [more] In flotation, interactions of bubble-particle aggregates with turbulent flow structures in the liquid medium result in particle detachment. This study aims to simulate this phenomenon involving a bubble-particle aggregate (bubble diameter ~ 3 mm and particle diameter ~ 314 µm) interacting with a turbulent flow structure manifested as a confined vortex in a square cavity connected to a square cross-section channel. An interface resolved three dimensional (3D) computational fluid dynamics (CFD) model was developed to quantify the bubble-vortex interaction dynamics over a range of channel Reynolds numbers. The CFD model produced a good agreement with the experimentally measured vorticity magnitude, local energy dissipation rate, and bubble motion. It was shown that a bubble-particle aggregate could be captured within the vortex by suitably varying the channel Reynolds number, eventually leading to particle detachment. A separate force balance analysis was performed to determine a criterion for particle detachment utilising the CFD model predicted vorticity and local energy dissipation rate. It was shown that a critical local energy dissipation rate ~ 1.59 m2/s3 was required for particle detachment to occur, which was also verified experimentally.
|
Nova | |||||||||
2020 |
Nguyen NN, Chu ATT, Sherman HM, Nguyen AV, Jameson GJ, 'A new paradigm of bubble-particle detachment interaction: How and where do the bubble and the particle detach?', Minerals Engineering, 159 (2020) [C1]
|
Nova | |||||||||
2020 |
Jameson GJ, Cooper L, Tang KK, Emer C, 'Flotation of coarse coal particles in a fluidized bed: The effect of clusters', Minerals Engineering, 146 (2020) [C1]
|
Nova | |||||||||
2019 |
Gautam S, Jameson GJ, 'The detachment of particles from bubbles at various locations in a turbulent flotation cell', Minerals Engineering, 132 316-325 (2019) [C1]
|
Nova | |||||||||
2019 |
Jameson GJ, Emer C, 'Coarse chalcopyrite recovery in a universal froth flotation machine', Minerals Engineering, 134 118-133 (2019) [C1]
|
Nova | |||||||||
2018 |
Ng WS, Cooper L, Connal LA, Forbes E, Jameson GJ, Franks GV, 'Tuneable collector/depressant behaviour of xanthate-functional temperature-responsive polymers in the flotation of copper sulfide: Effect of shear and temperature', MINERALS ENGINEERING, 117 91-99 (2018) [C1]
|
Nova | |||||||||
2017 |
Bournival G, Ata S, Jameson GJ, 'Bubble and Froth Stabilizing Agents in Froth Flotation', Mineral Processing and Extractive Metallurgy Review, 38 366-387 (2017) [C1]
|
Nova | |||||||||
2017 |
Wang G, Evans GM, Jameson GJ, 'Bubble movement in a rotating eddy: The implications for particle-bubble detachment', CHEMICAL ENGINEERING SCIENCE, 161 329-340 (2017) [C1]
|
Nova | |||||||||
2017 |
Wang G, Evans GM, Jameson GJ, 'Bubble-particle detachment in a turbulent vortex II-Computational methods', MINERALS ENGINEERING, 102 58-67 (2017) [C1]
|
Nova | |||||||||
2016 |
Wang G, Nguyen AV, Mitra S, Joshi JB, Jameson GJ, Evans GM, 'A review of the mechanisms and models of bubble-particle detachment in froth flotation', Separation and Purification Technology, 170 155-172 (2016) [C1] Only when the process of particle detachment is well understood and modelled can minerals recovery using the flotation process be modulated to achieve a high efficiency by suitabl... [more] Only when the process of particle detachment is well understood and modelled can minerals recovery using the flotation process be modulated to achieve a high efficiency by suitably changing the operating parameters. This is vitally necessary for the recovery of coarse particles in an energy efficient way, as detachment is the key limiting factor in the successful recovery of large particles. However, until the detachment mechanism is more fully understood, an upper limit on the floatable particle diameter still remains unidentified. To assess the current state of knowledge available in this area, a comprehensive literature review on the mechanisms and models of the bubble-particle detachment process in froth flotation is presented. In general, the detachment process is considered to be a stochastic process, and is usually attributed to the dynamic interactions with the turbulent flow structures (eddies) in the flotation environment which cause particles to detach because of dissipating energy. In this paper, previous studies on bubble-particle detachment have been critically analyzed with respect to the formulation of the models in predicting the detachment probability of particles. The models are classified into three different categories: force balance analysis; energy balance analysis and empirical analysis of particle size compared to maximum floatable particle size. Attention is also paid to an understanding of the mechanisms of bubble-particle detachment in quiescent and turbulent liquid flow fields. The predictions of all these models have been compared with the published experimental data and it was found that models which take an accurate consideration of the influence of eddies on a particle's detachment give the closest predictions. The generally held concept of bubble-particle detachment inside an eddy was experimentally validated, where a particle was observed to rotate on the surface of a bubble, resulting in a centrifugal acceleration 20 times that of gravitational acceleration. The aim of this paper is to review the developments and limitations of the existing models. The experimental work is reviewed so as to reveal the mechanisms of bubble-particle detachment. Therefore, the future development of models is identified in order to successfully predict particle detachment.
|
Nova | |||||||||
2016 |
Wang G, Evans GM, Jameson GJ, 'Experiments on the detachment of particles from bubbles in a turbulent vortex', Powder Technology, 302 196-206 (2016) [C1] In this paper we present a new method for studying the detachment of particles from bubbles in a rotating turbulent eddy. The eddy is formed in a wall cavity in a two-dimensional ... [more] In this paper we present a new method for studying the detachment of particles from bubbles in a rotating turbulent eddy. The eddy is formed in a wall cavity in a two-dimensional water tunnel with transparent walls. When water flows through the tunnel, a vortical flow field develops in the cavity. The properties of the eddy can be modulated by changing the free-stream velocity of the water in the tunnel. Bubbles are pre-loaded with one or more particles in a fluidized bed flotation device located beneath the vortex cavity. Loaded bubbles are released one at a time into the cavity, and the motion of the bubble-particle aggregate is studied using a high-speed video camera. The diameters of the particles and the bubbles, and the number of particles initially attached to the bubble, can be varied. The trajectories taken by the bubbles are quite complicated. In some cases, the bubble moves to the centre of the eddy, and particles rotate around its axis. If the rotational speed is sufficient, particles may detach due to centrifugal force. However, other modes were observed, including inertial detachment due to rapid changes in direction of the surface of the bubble, because of changes in trajectory of the bubble as a whole, or because of pulsations and oscillations of the bubble surface. Clusters of bubbles held together by particles were seen to form and reform. In the traditional explanation for the detachment of particles in flotation cells, it is assumed that particles detach from bubbles rotating in an eddy due to centrifugal force (Schulze, 1977) [1]. Although the conditions assumed in Schulze's theory may exist, it is only one of a range of phenomena that can lead to the detachment of particles from bubbles in a turbulent vortex. The interactions between bubbles and particles is stochastic in nature, and it is impossible to model precisely the series of events that take place when a particle and a bubble make contact with each other and move through the liquid. There can be no simple model for the recovery of hydrophobic particles in flotation machines.
|
Nova | |||||||||
2016 |
Wang G, Evans GM, Jameson GJ, 'Bubble-particle detachment in a turbulent vortex I: Experimental', MINERALS ENGINEERING, 92 196-207 (2016) [C1]
|
Nova | |||||||||
2015 |
Chen Z, Ata S, Jameson GJ, 'Break-up of bubble clusters in turbulent flow-Theory', Powder Technology, 279 228-232 (2015) [C1] The behaviour of bubble clusters in turbulent conditions has been studied theoretically. The cluster behaviour was modelled based on concept drawn from the related field of bubble... [more] The behaviour of bubble clusters in turbulent conditions has been studied theoretically. The cluster behaviour was modelled based on concept drawn from the related field of bubble breakup. It was assumed that the bubbles were bridged by particles, so the cohesive strength was determined by the capillary force between the bubbles and the particles. Two different theories were investigated for the disruptive force from the turbulent liquid: the shear rate hypothesis of Camp and Stein (1943), and the turbulent fluctuation model arising from Kolmogorov's theory of isotropic turbulence (Kolmogorov, 1941). It was found that neither method is applicable in the fragmentation stage. However, in the equilibrium stage, an equation derived from Camp and Stein's theory was more realistic than that obtained using Kolmogorov's equation.
|
Nova | |||||||||
2015 | Jameson G, 'Back to basics: Getting physical', TCE The Chemical Engineer, 44-47 (2015) [C3] | ||||||||||
2015 |
Chen Z, Ata S, Jameson GJ, 'Behaviour of bubble clusters in a turbulent flotation cell', Powder Technology, 269 337-344 (2015) [C1] The rate of capture of particles decreases as the particle size increases in froth flotation. It has been postulated that the upper size range of particles that can be recovered i... [more] The rate of capture of particles decreases as the particle size increases in froth flotation. It has been postulated that the upper size range of particles that can be recovered in conventional machines could be extended by the use of bubble clusters [1].This study is concerned with the behaviour of bubble clusters in turbulent flotation cell. The breakup and re-formation of clusters and the effect of bubble size and impeller speed on the behaviour of clusters have been investigated. The apparatus used was essentially a laboratory flotation cell, agitated by a Rushton turbine. The cell was modified to allow pre-formed clusters to rise out of a fluidized bed and into the path of the rotating impeller. The events were captured using a digital camera, and the images were analysed to give the sizes of the bubbles and clusters.In the first part of the investigation, a collector was used but no frother. Under these conditions, the bubble diameter was effectively controlled by the collector concentration, and it varied considerably. It was found that the sizes of clusters decrease with increasing shear rate at low impeller speeds, and at higher speeds the clusters are broken up into bubbles and particles.In the second part, frother was used at a concentration above the critical coalescence concentration, to control the bubble size, which remained essentially constant at this concentration. The bubbles were too small to be broken by the action of the impeller, so they always remained at the same size. In this case it was found that when the impeller speed was increased, two stages of formation were observed, the fragmentation and equilibrium stages. In the fragmentation stage, at low impeller speeds, the clusters were loose and filamentous, and as the energy input increases, they rupture and re-form. In the second stage, above a critical impeller speed, dense clusters formed whose size was relatively insensitive to the energy input.
|
Nova | |||||||||
2015 |
Rahman RM, Ata S, Jameson GJ, 'Study of froth behaviour in a controlled plant environment - Part 1: Effect of air flow rate and froth depth', Minerals Engineering, 81 152-160 (2015) [C1] This paper presents the results of a thorough investigation into the froth recovery measurements in a controlled plant environment using a device that allows direct collection of ... [more] This paper presents the results of a thorough investigation into the froth recovery measurements in a controlled plant environment using a device that allows direct collection of dropback particles from the froth phase. Experiments were performed at the Northparkes concentrator (NSW, Australia), using a feed taken from the head of the cleaner scavenger bank. The feed slurry had a relatively higher copper grade varying from 5.2% to 6.8%. Experiments were performed to investigate the effect of important flotation parameters such as air flow rate and froth depth, on the froth performance. The size of the particles in the relevant streams was analysed to acquire in-depth knowledge about the froth dropback mechanism. The results suggested that the froth recovery could be as low as 70%, although it was relatively easy to achieve the values in the range 75-85% by the correct choice of operating variables. It was found that the air flow rate has a positive impact on both collection (pulp) and froth zone recoveries. However, the effect was more prominent in the froth zone. It appeared that the froth recovery is a strong function of particle size.
|
Nova | |||||||||
2015 |
Rahman RM, Ata S, Jameson GJ, 'Study of froth behaviour in a controlled plant environment - Part 2: Effect of collector and frother concentration', Minerals Engineering, 81 161-166 (2015) [C1] An investigation into froth zone recovery in a controlled plant environment is presented. The effect of operating conditions on the froth performance is given in our previous work... [more] An investigation into froth zone recovery in a controlled plant environment is presented. The effect of operating conditions on the froth performance is given in our previous work (Rahman et al., 2015). This paper is primarily concerned with the influence of chemical properties such as frother and collector concentration on the froth behaviour. The results suggested that increasing the collector concentration gave expected results in the collection (pulp) zone, with a significant increase in coarse particle recovery. However, at high collector concentrations, it was observed that there was an increase in bubble coalescence and froth instability as well as a slight decrease in froth recovery. Increasing frother concentration gave a significant improvement in froth recovery and a slight increase in the collection zone recovery was also found. This was attributed to the formation of finer, more stable, bubbles and a corresponding increase in froth stability. Size and grade analysis of the samples suggested that the dropback particles were mainly composite or middling fractions. It appeared that particles whose grade was higher than the feed may be collected into the froth zone, but some particles with grades lower than the concentrate may detach from the froth.
|
Nova | |||||||||
2015 |
Chen Z, Ata S, Jameson GJ, 'Breakup and re-formation of bubble clusters in a flotation cell', Minerals Engineering, 71 16-20 (2015) [C1] This study is concerned with the behavior of bubble clusters in a well-controlled turbulent flow. We used a specially designed cell where the bubble aggregates could be formed and... [more] This study is concerned with the behavior of bubble clusters in a well-controlled turbulent flow. We used a specially designed cell where the bubble aggregates could be formed and exposed to breakage by a rotating impeller. The effects of impeller speed and the concentration of collector on cluster behavior were studied. It was found that the size of the clusters increases with the concentration of collector used. We also found that although the clusters could easily be destroyed under the action of impeller, they could reform, especially at lower impeller speeds. It was observed that the size of the bubbles arriving into the impeller region in the absence of particles before breakage was considerably higher than the size of the clusters formed at the same impeller speed. It appears that both cluster breakage and re-formation take place simultaneously, and the extent of formation and regrowth is mainly determined by the hydrophobicity of the particles and the impeller speed.
|
Nova | |||||||||
2014 |
Bournival G, Du Z, Ata S, Jameson GJ, 'Foaming and gas dispersion properties of non-ionic frothers in the presence of hydrophobized submicron particles', INTERNATIONAL JOURNAL OF MINERAL PROCESSING, 133 123-131 (2014) [C1]
|
Nova | |||||||||
2014 |
Wang G, Zhou S, Joshi JB, Jameson GJ, Evans GM, 'An energy model on particle detachment in the turbulent field', Minerals Engineering, 69 165-169 (2014) [C1] A flotation detachment model is developed by considering energy balance in the process. Energies concerned are surface energy increment and kinetic energy supplied by turbulent li... [more] A flotation detachment model is developed by considering energy balance in the process. Energies concerned are surface energy increment and kinetic energy supplied by turbulent liquid motion. Surface energy increment is the work of adhesion by surface forces which is reflected by surface tension and contact angle. What makes this model outstanding from other detachment models of energy balance perspective is more accurate account of kinetic energy supplied from turbulent liquid motion. Eddies in the same scale as attached particles are considered accountable for particle detachment in the close vicinity. In this way, detachment probability is written as a function of energy dissipation rate. Predictions from different models are compared to experimental results. It is demonstrated that previous models overestimate the influence from turbulent liquid motion. Notably, with more accurate account of eddies' influence, the new model predicts particle detachment in accordance with experimental results.
|
Nova | |||||||||
2014 |
Bournival G, Ata S, Jameson GJ, 'The influence of submicron particles and salt on the recovery of coarse particles', Minerals Engineering, 69 146-153 (2014) [C1] Coarse particles are more difficult to float. One of the factors that contributes to poor floatability is the stability of froth. The froth formed in industrial flotation cells is... [more] Coarse particles are more difficult to float. One of the factors that contributes to poor floatability is the stability of froth. The froth formed in industrial flotation cells is typically not strong enough to provide adequate support for coarse and dense particles. The present study investigates how the presence of hydrophobic submicron particles at low concentration increases the recovery of relatively coarse particles through improvement in the froth stability. Silica particles with d80 of approximately 230 µm were floated in a laboratory mechanical flotation cell in a collector-free environment in the presence of poly(propylene glycol) 425 as a frothing agent. The hydrophobicity of the feed particles was modified through an esterification process with different alcohols ranging from 3 to 8 hydrocarbon groups to form a coating of intermediate hydrophobicity. Hydrophobised silica submicron particles of 300 nm in size were added to the flotation cell at 0.01 and 0.1 wt% concentration. The effect of electrolyte, sodium chloride, in the concentration range 10-5-10-1 M on the recovery of coarse particles was also investigated. For the feed employed, 1-butanol was found to provide relatively good flotation properties with a possibility for improvement by stabilising the froth phase. Both additives slightly stabilised the froth phase, which resulted in an increase in the maximum recovery of up to approximately 8%. It appeared that the additives had no significant effect on the first-order flotation rate constant.
|
Nova | |||||||||
2014 |
Wang G, Sathe M, Mitra S, Jameson GJ, Evans GM, 'Detachment of a bubble anchored to a vertical cylindrical surface in quiescent liquid and grid generated turbulence', Canadian Journal of Chemical Engineering, 92 2067-2077 (2014) [C1] Turbulence plays a critical role in detachment process of bubble from a solid surface. To investigate this effect, detachment process of a stationary air bubble from a nozzle in b... [more] Turbulence plays a critical role in detachment process of bubble from a solid surface. To investigate this effect, detachment process of a stationary air bubble from a nozzle in both quiescent and turbulent liquid field was studied. A stationary vertical (flat-ended) needle of ID 1.24mm was used as a nozzle to generate a bubble which was anchored to the needle tip. Different sizes of bubbles were generated in quiescent liquid. Volume and contact angle for these bubbles were measured precisely using microscopic imaging technique and correlated. In the quiescent case experiments, a constant contact angle of 90° and bubble diameter of 3.05±0.004mm were obtained consistently. A simple force balance approach was proposed assuming bubble in equilibrium to determine this maximum bubble diameter during detachment. The detached bubble size calculated using this approach agreed fairly well with the experimental results. An oscillating grid device capable of operating at different frequencies was then applied to generate a homogeneous, near-isotropic turbulent velocity field around the anchored bubble. It was observed that for detachment of smaller bubbles, higher turbulence intensity was indeed necessary. The turbulent flow field was quantified using particle image velocimetry (PIV) technique and resolved into flow structures (eddies) of different length scales using a Gaussian filter. It was concluded that smaller eddies perturbed the bubble interface whilst the larger eddies contributed to weakening of the capillary force causing the bubble detachment. Energy dissipation profile obtained from the PIV images indicated significant energy dissipation near the bubble compared to the bulk fluid which supported the fact that strong interactions between bubble and eddies were indeed responsible for bubble detachment.
|
Nova | |||||||||
2014 |
Bournival G, Ata S, Karakashev SI, Jameson GJ, 'An investigation of bubble coalescence and post-rupture oscillation in non-ionic surfactant solutions using high-speed cinematography', JOURNAL OF COLLOID AND INTERFACE SCIENCE, 414 50-58 (2014) [C1]
|
Nova | |||||||||
2014 |
Ireland PM, Jameson GJ, 'Collision of a rising bubble-particle aggregate with a gas-liquid interface', International Journal of Mineral Processing, 130 1-7 (2014) [C1] In this paper we investigate the hypothesis that when bubbles carrying attached hydrophobic particles arrive at an air-liquid interface, the abrupt change in velocity is sufficien... [more] In this paper we investigate the hypothesis that when bubbles carrying attached hydrophobic particles arrive at an air-liquid interface, the abrupt change in velocity is sufficient to dislodge attached particles, which fall back into the liquid. For the first time, experiments have demonstrated a case in which the particles do not detach, but move smoothly over the surface of the bubbles. The kinetic energy of arrival is dissipated by the motion of the particles through the liquid, as they move over the surface of the bubble while remaining attached. Some energy is also dissipated by the pulsations of the bubbles. The pulsations themselves do not lead to detachment of particles. A theory has been developed to explain the observed phenomena. © 2014 Published by Elsevier B.V.
|
Nova | |||||||||
2014 |
Curry JA, Ismay MJL, Jameson GJ, 'Mine operating costs and the potential impacts of energy and grinding', Minerals Engineering, 56 70-80 (2014) [C1] An understanding of the breakdown of mine costs is an important tool for researchers and developers who seek to place novel cost-reducing unit operations in the wider general cost... [more] An understanding of the breakdown of mine costs is an important tool for researchers and developers who seek to place novel cost-reducing unit operations in the wider general cost context. This paper provides a breakdown of operating costs in 63 mines by dividing them into three main categories: mining, milling, and general and administrative (G & A) costs. The study looks at patterns in mining type, mill processing type, mineral type, and the differences between costs expressed in feasibility studies vs. operating mines. The paper explores the reasons for the relationships observed and then presents a total average mine cost breakdown. It was found that the mean relative mining and milling costs did not differ significantly, and that on average they had equal shares of the total enterprise operating costs. Effects of mine and mineral type were observed, with underground milling costs being significantly less than open pit milling costs and gold mines occupying a significantly larger share of mine operating costs than copper-containing mines. The overall relative operating costs were found to be in the ratios between (43:43:14) and (45:45:10) (Mine:Mill:G & A). A treatment of potential unit operations and innovative technologies is provided at the conclusion of the paper, including coarse particle recovery by flotation and novel grinding technologies. © 2013 Published by Elsevier Ltd.
|
Nova | |||||||||
2014 |
Bournival G, Du Z, Ata S, Jameson GJ, 'Foaming and gas dispersion properties of non-ionic surfactants in the presence of an inorganic electrolyte', Chemical Engineering Science, 116 536-546 (2014) [C1] Foams represent an important area of research due to their relevance in many industrial processes. Where there are geographical constraints, which can limit access to fresh water,... [more] Foams represent an important area of research due to their relevance in many industrial processes. Where there are geographical constraints, which can limit access to fresh water, there is an economic incentive in using recycled water, bore water and even seawater for industrial purposes. This creates a growing interest in determining the effect of inorganic electrolytes on foaming and gas dispersion properties of non-ionic surfactant solutions. The present study compares the foaming and gas dispersion properties of the non-ionic surfactants 1-pentanol, tri(propylene glycol) methyl ether, and poly(propylene glycol) 425. For all surfactants, the stabilisation mechanism was influenced by the concentration of surfactant and the presence of salt with PPG being affected to a lesser extent. Sodium chloride was observed to have a detrimental effect on foaming at higher surfactant concentrations but improved foaming at low surfactant concentrations. At low surfactant concentrations, the addition of salt improved foaminess by dampening the hydrophobic force. An increase in gas holdup with increasing surfactant concentration was observed and was attributed to a decrease in bubble size. For poly(propylene glycol) an initial decrease in gas holdup was observed at very low concentrations. Salt mainly affected gas dispersion properties at a higher concentration. © 2014 Elsevier Ltd.
|
Nova | |||||||||
2013 |
Ireland PM, Jameson GJ, 'Particle dynamics in cyclone tribochargers', JOURNAL OF ELECTROSTATICS, 71 449-455 (2013) [C1]
|
Nova | |||||||||
2013 |
Ata S, Jameson GJ, 'Recovery of coarse particles in the froth phase - A case study', MINERALS ENGINEERING, 45 121-127 (2013) [C3]
|
||||||||||
2012 |
Neville FC, Mohd Zin AB, Jameson GJ, Wanless EJ, 'Preparation and characterization of colloidal silica particles under mild conditions', Journal of Chemical Education, 89 940-942 (2012) [C1]
|
Nova | |||||||||
2012 |
Ireland PM, Jameson GJ, 'Drag force on a spherical particle moving through a foam: The role of wettability', International Journal of Mineral Processing, 102-103 78-88 (2012) [C1]
|
Nova | |||||||||
2012 |
Rahman RM, Ata S, Jameson GJ, 'The effect of flotation variables on the recovery of different particle size fractions in the froth and the pulp', International Journal of Mineral Processing, 106 70-77 (2012) [C1]
|
Nova | |||||||||
2012 |
Jameson GJ, 'The effect of surface liberation and particle size on flotation rate constants', Minerals Engineering, 36-38 132-137 (2012) [C1]
|
Nova | |||||||||
2012 |
Gautam A, Jameson GJ, 'The capillary force between a bubble and a cubical particle', Minerals Engineering, 36-38 291-299 (2012) [C1]
|
Nova | |||||||||
2012 |
Goel S, Jameson GJ, 'Detachment of particles from bubbles in an agitated vessel', Minerals Engineering, 36-38 324-330 (2012) [C1]
|
Nova | |||||||||
2012 |
Moberg AK, Ellem GK, Jameson GJ, Herbertson JG, 'Simulated cell trajectories in a stratified gas-liquid flow tubular photobioreactor', Journal of Applied Phycology, 24 357-363 (2012) [C1]
|
Nova | |||||||||
2011 |
Ata S, Pugh RJ, Jameson GJ, 'The influence of interfacial ageing and temperature on the coalescence of oil droplets in water', Colloids and Surfaces A: Physicochemical and Engineering Aspects, 374 96-101 (2011) [C1]
|
Nova | |||||||||
2010 |
Jameson GJ, 'Advances in fine and coarse particle flotation', Canadian Metallurgical Quarterly, 49 328-330 (2010) [C1]
|
Nova | |||||||||
2010 |
Button EC, Davidson JF, Jameson GJ, Sader JE, 'Water bells formed on the underside of a horizontal plate. Part 2. Theory', Journal of Fluid Mechanics, 649 45-68 (2010) [C1]
|
Nova | |||||||||
2010 |
Jameson GJ, Jenkins CE, Button EC, Sader JE, 'Water bells formed on the underside of a horizontal plate. Part 1. Experimental investigation', Journal of Fluid Mechanics, 649 19-43 (2010) [C1]
|
Nova | |||||||||
2010 |
Jameson GJ, 'New directions in flotation machine design', Minerals Engineering, 23 835-841 (2010) [C1]
|
Nova | |||||||||
2009 |
Ireland PM, Jameson GJ, 'Foam slip on surfaces of intermediate or low wettability', Chemical Engineering Science, 64 3859-3867 (2009) [C1]
|
Nova | |||||||||
2009 |
Zhou Y, Yu H, Wanless EJ, Jameson GJ, Franks GV, 'Influence of polymer charge on the shear yield stress of silica aggregated with adsorbed cationic polymers', Journal of Colloid and Interface Science, 336 533-543 (2009) [C1]
|
Nova | |||||||||
2009 |
Hunter TN, Jameson GJ, Wanless EJ, Dupin D, Armes SP, 'Adsorption of submicrometer-sized cationic sterically stabilized polystyrene latex at the air-water interface: Contact angle determination by ellipsometry', Langmuir, 25 3440-3449 (2009) [C1]
|
Nova | |||||||||
2009 |
Hunter TN, Wanless EJ, Jameson GJ, 'Effect of esterically bonded agents on the monolayer structure and foamability of nano-silica', Colloids and Surfaces A: Physicochemical and Engineering Aspects, 334 181-190 (2009) [C1]
|
Nova | |||||||||
2009 |
Hunter TN, Wanless EJ, Jameson GJ, Pugh RJ, 'Non-ionic surfactant interactions with hydrophobic nanoparticles: Impact on foam stability', Colloids and Surfaces A: Physicochemical and Engineering Aspects, 347 81-89 (2009) [C1]
|
Nova | |||||||||
2008 | Jameson GJ, Jenkins C, Button EC, Sader JE, 'Water bells created from below', Physics of Fluids, 20 091108 (2008) [C3] | Nova | |||||||||
2008 |
Hunter TN, Pugh RJ, Franks GV, Jameson GJ, 'The role of particles in stabilising foams and emulsions', Advances in Colloid and Interface Science, 137 57-81 (2008) [C1]
|
Nova | |||||||||
2008 |
Olsen AH, Franks GV, Biggs S, Jameson GJ, 'Collision efficiency factor for heteroaggregation: Extension to soft interactions', Journal of Chemical Physics, 128 044913 (2008) [C1]
|
Nova | |||||||||
2008 |
Zhou Y, Gan Y, Wanless EJ, Jameson GJ, Franks GV, 'Interaction forces between silica surfaces in aqueous solutions of cationic polymeric flocculants: Effect of polymer charge', Langmuir, 24 10920-10928 (2008) [C1]
|
Nova | |||||||||
2008 |
Yates PD, Franks GV, Jameson GJ, 'Orthokinetic heteroaggregation with nanoparticles: Effect of particle size ratio on aggregate properties', Colloids and Surfaces A: Physicochemical and Engineering Aspects, 326 83-91 (2008) [C1]
|
Nova | |||||||||
2008 |
Zhou Y, Jameson GJ, Franks GV, 'Influence of polymer charge on the compressive yield stress of silica aggregated with adsorbed cationic polymers', Colloids and Surfaces A: Physicochemical and Engineering Aspects, 331 183-194 (2008) [C1]
|
Nova | |||||||||
2007 |
Ireland PM, Cunningham R, Jameson GJ, 'The behaviour of wash water injected into a froth', International Journal of Mineral Processing, 84 99-107 (2007) [C1]
|
||||||||||
2007 |
Hunter TN, Jameson GJ, Wanless EJ, 'Determination of contact angles of nanosized silica particles by multi-angle single-wavelength ellipsometry', Australian Journal of Chemistry, 60 651-655 (2007) [C1]
|
Nova | |||||||||
2007 |
Ireland PM, Jameson GJ, 'Liquid transport in a coalescing froth', Canadian Journal of Chemical Engineering, 85 654-661 (2007) [C1]
|
||||||||||
2007 |
Jameson GJ, Parekh VV, 'Effect of n-alcohols on the stability of bubbles', Canadian Metallurgical Quarterly, 46 311-320 (2007) [C1]
|
||||||||||
2007 |
Ireland PM, Jameson GJ, 'Liquid transport in a multi-layer froth', Journal of Colloid and Interface Science, 314 207-213 (2007) [C1]
|
Nova | |||||||||
2007 |
Stevenson P, Jameson GJ, 'Modelling continuous foam fractionation with reflux', Chemical Engineering and Processing: Process Intensification, 46 1286-1291 (2007) [C1]
|
||||||||||
2006 |
Olsen AH, Franks GV, Biggs S, Jameson GJ, 'An improved collision efficiency model for particle aggregation', Journal of Chemical Physics, 125 (2006) [C1]
|
||||||||||
2006 |
Jameson GJ, 'Selected papers from the Centenary of Flotation Symposium, 5-9 June 2005, Brisbane, Australia - Foreword', MINERALS ENGINEERING, 19 529-530 (2006)
|
||||||||||
2006 |
Nguyen AV, Alexandrova L, Grigorov L, Jameson GJ, 'Dewetting kinetics on silica substrates: Three phase contact expansion measurements for aqueous dodecylammonium chloride films', Minerals Engineering, 19 651-658 (2006) [C1]
|
||||||||||
2006 |
Ata S, Pigram SM, Jameson GJ, 'Tracking of particles in the froth phase: An experimental technique', Minerals Engineering, 19 824-830 (2006) [C1]
|
||||||||||
2006 | Jameson GJ, 'Minerals Engineering: Foreword (editorial)', Minerals Engineering, 19 529-530 (2006) [C3] | ||||||||||
2006 | Jameson GJ, 'Selected papers from the Centenary of Flotation Symposium, 5-9 June 2005, Brisbane, Australia', Minerals Engineering, 19 340 (2006) [C2] | ||||||||||
2006 |
Franks GV, Sepulveda CV, Jameson GJ, 'PH-sensitive flocculation: Settling rates and sediment densities', AICHE Journal, 52 2774-2782 (2006) [C1]
|
||||||||||
2006 |
Nguyen AV, George PF, Jameson GJ, 'Demonstration of a minimum in the recovery of nanoparticles by flotation: Theory and experiment', Chemical Engineering Science, 61 2494-2509 (2006) [C1]
|
Nova | |||||||||
2005 |
Olsen AH, Franks GV, Biggs S, Jameson GJ, 'Bi-modal Hetro-aggregation Rate Response to Particle Dosage', Journal of Chemical Physics, 123 - (2005) [C1]
|
Nova | |||||||||
2005 |
Franks GV, Yates PD, Lambert NW, Jameson GJ, 'Aggregate size and density after shearing, implications for dewatering fine tailings with hydrocyclones', International Journal of Mineral Processing, 77 46-52 (2005) [C1]
|
Nova | |||||||||
2005 |
Nguyen AV, Jameson GJ, 'Sliding of fine particles on the slip surface of rising gas bubbles: Resistance of liquid shear flows', International Journal of Multiphase Flow, 31 492-513 (2005) [C1]
|
||||||||||
2005 |
Ata S, Jameson GJ, 'The formation of bubble clusters in flotation cells', International Journal of Mineral Processing, 76 123-139 (2005) [C1]
|
Nova | |||||||||
2005 |
Harvey PA, Nguyen AV, Jameson GJ, Evans GM, 'Influence of sodium dodecyl sulphate and Dowfroth frothers on froth stability', Minerals Engineering, 18 311-315 (2005) [C1]
|
Nova | |||||||||
2005 |
Yates PD, Franks GV, Biggs S, Jameson GJ, 'Heteroaggregation with nanoparticles: effect of particle size ratio on optimum particle dose', Colloids and Surfaces a-Physicochemical and Engineering Aspects, 255 85-90 (2005) [C1]
|
||||||||||
2005 |
Evans GM, Manning SA, Jameson GJ, 'Cavity formation, growth, and dispersion behind rotating impeller blades', Industrial & Engineering Chemistry Research, 44 6304-6309 (2005) [C1]
|
Nova | |||||||||
2005 |
Ata S, Pigram S, Jameson GJ, 'Tracking of particles in the froth phase - an experimental technique', Australasian Institute of Mining and Metallurgy Publication Series, 309-313 (2005) This paper is concerned with the tracking of particles in the froth phase of an aerated water/glycerol mixture. Experiments have been carried out in a specially designed laborator... [more] This paper is concerned with the tracking of particles in the froth phase of an aerated water/glycerol mixture. Experiments have been carried out in a specially designed laboratory flotation cell that allows formation of a deep froth. Phosphorescent tracer particles of various sizes were injected into the centre of a froth column where they were excited by ultraviolet lights, positioned at the back and front of the column. The motion of particles was captured on a digital camera with a green filter. The images from the digital camera were then transferred to a computer and an image analysis program was used to convert the colour intensity to the concentration of particles at each location within the froth. The tracer technique was used to determine the dispersion of hydrophilic particles and the variation of the concentration of solids with axial and radial positions. |
||||||||||
2005 |
Ata S, Agarwal A, Jameson GJ, 'The Formation of Bubble Clusters in Flotation Cells - Effect of Impeller Speed', Australasian Institute of Mining and Metallurgy Publication Series, 403-406 (2005) This paper is concerned with the observation and analysis of bubble clusters in a laboratory flotation cell. A device was used in which bubbles were allowed to rise in clean water... [more] This paper is concerned with the observation and analysis of bubble clusters in a laboratory flotation cell. A device was used in which bubbles were allowed to rise in clean water containing the same frother and collector concentration as in the cell. Bubble clusters were recorded using a high speed camera and analysed using an image analyser. Dodecyl amine was employed as a collector to float silica. The effect of impeller speed on the cluster behaviour was investigated. The results were interpreted in terms of cluster diameter and shape factor. The sizes of the bubbles forming the clusters were also measured and compared to the sizes of the independent bubbles in the cell. It was found that there was an optimum impeller speed in which the cluster diameter was a maximum. Higher agitation and the consequent higher power inputs resulted in cluster break-up while lower shear rates promoted cluster formation. |
||||||||||
2005 |
Alexandrova L, Nguyen AV, Grigorov L, Jameson GJ, 'Dewetting kinetics on silica substrates - three-phase contact expansion measurements for aqueous dodecylammonium chloride films', Australasian Institute of Mining and Metallurgy Publication Series, 397-402 (2005) The dewetting kinetics between a small air-liquid interface and a silica (negatively charged in water) planar surface in solutions of dodecylammonium chloride (cationic surfactant... [more] The dewetting kinetics between a small air-liquid interface and a silica (negatively charged in water) planar surface in solutions of dodecylammonium chloride (cationic surfactant) has been investigated using the Scheludko cell and digital high-speed video microscopy. The gas-liquid interface was created at the bottom of a small silica capillary of the cell and then was moved towards the silica planar surface. After the rupture of the liquid films between the interfaces, the expansion of the gas-liquid-solid three-phase contact (TPC) line was observed and recorded using a digital high-speed video microscope system, operating at 1000 frames per second. The surface tension of the surfactant solution was measured using the pendant drop technique. The equilibrium contact angle was measured using the Scheludko-Minings method with a silica micro-sphere. The TPC radius was determined as a function of time and compared against the available hydrodynamic and molecular-kinetic models. The experimental data are described very well by the molecular-kinetic model for the TPC line motion. The hydrodynamic model is in agreement with the experimental data only for a short time after inception of the three-phase contact expansion. |
||||||||||
2004 |
Yan Y, Jameson GJ, 'Application of the Jameson Cell technology for algae and phosphorus removal from maturation ponds', Int. Journal of Mineral Processing, 73 23-28 (2004) [C1]
|
||||||||||
2004 |
Yan Y, Glover SM, Jameson GJ, Biggs SR, 'The flocculation efficiency of polydisperse polymer flocculants', Int. Journal of Mineral Processing, 73 161-175 (2004) [C1]
|
||||||||||
2004 |
Glover SM, Yan Y, Jameson GJ, Biggs SR, 'Dewatering properties of dual-polymer-flocculated systems', Int. Journal of Mineral Processing, 73 145-160 (2004) [C1]
|
||||||||||
2004 |
Ata S, Ahmed N, Jameson GJ, 'The effect of hydrophobicity on the drainage of gangue minerals in flotation froths', Minerals Engineering, 17 897-901 (2004) [C1]
|
||||||||||
2004 |
George PF, Nguyen AV, Jameson GJ, 'Assessment of true flotation and entrainment in the flotation of submicron particles by fine bubbles', Minerals Engineering, 17 847-853 (2004) [C1]
|
||||||||||
2004 |
Franks GV, Zhou Y, Yan Y, Jameson GJ, Biggs SR, 'Effect of aggregate size on sediment bed rheological properties', Physical Chemistry Chemical Physics, 6 4490-4498 (2004) [C1]
|
Nova | |||||||||
2003 |
Atkinson B, Jameson GJ, Nguyen AV, Evans GM, Machniewski PM, 'Bubble Breakup and Coalescence in a Plunging Liquid Jet bubble Column', The Canadian Journal of Chemical Engineering, 81 519-527 (2003) [C1]
|
||||||||||
2003 |
Stevenson P, Sullivan SP, Jameson GJ, 'Short-time tracer dispersion in a two-dimensional rising froth', Chemical Engineering Science, 58 5025-5043 (2003) [C1]
|
||||||||||
2003 |
Atkinson B, Jameson GJ, Nguyen AV, Evans GM, 'Increasing Gas - Liquid Contacting Using a Confined Plunging Liquid Jet', Journal of Chemical Technology and Biotechnology, 78 269-275 (2003) [C1]
|
||||||||||
2003 |
Ata S, Ahmed N, Jameson GJ, 'A Study of bubble Coalescence in Flotation Froths', International Journal of Mineral Processing, 72 255-266 (2003) [C1]
|
Nova | |||||||||
2003 |
Phan MC, Nguyen AV, Miller JD, Evans GM, Jameson GJ, 'Investigations of Bubble-Particle Interactions', International Journal of Mineral Processing, 72 239-254 (2003) [C1]
|
||||||||||
2003 |
Nguyen AV, Harvey PA, Jameson GJ, 'Influence of Gas Flow Rate and Frothers on Water Recovery in a Froth Column', Minerals Engineering, 16 1143-1147 (2003) [C1]
|
||||||||||
2003 |
Stevenson P, Stevanov C, Jameson GJ, 'Liquid Overflow from a Column of Rising Aqueous Froth', Minerals Engineering, 16 1045-1053 (2003) [C1]
|
||||||||||
2003 |
Burns JL, Yan Y, Jameson GJ, Biggs SR, 'The Rheology of Concentrated Suspensions of Depletion-Flocculated Latex Particles', Colloids and Surfaces A, 214 173-180 (2003) [C1]
|
Nova | |||||||||
2002 |
Burns JL, Yan Y, Jameson GJ, Biggs S, 'The effect of molecular weight of nonadsorbing polymer on the structure of depletion-induced flocs', Journal of Colloid and Interface Science, 247 24-32 (2002) [C1]
|
Nova | |||||||||
2002 |
Biggs SR, Burns JL, Yan Y, Jameson G, Jenkins P, 'Viscosity effect on the structural compactness of latex flocs formed under weak depletion attractions', Journal of Colloid and Interface Science, 255 91-97 (2002) [C1]
|
||||||||||
2002 |
Ata S, Ahmed N, Jameson GJ, 'Collection of hydrophobic particles in the froth phase', International Journal of Mineral Processing, 64 101-122 (2002) [C1]
|
Nova | |||||||||
2002 |
Magrabi SA, Dlugogorski BZ, Jameson GJ, 'A comparative study of drainage characteristics in AFFF and FFFP compressed-air fire-fighting foams', Fire Safety Journal, 37 21-52 (2002) [C1]
|
||||||||||
2001 |
Magrabi SA, Dlugogorski BZ, Jameson GJ, 'Free drainage in aqueous foams: model and experimental study', AIChE Journal, 47 No. 2 314-327 (2001) [C1]
|
||||||||||
2000 |
Nguyen AV, Evans GM, Jameson GJ, 'Simple approximate expressions for electrical double-layer interaction at constant moderate potentials', Journal of Colloid and Interface Science, 230 205-209 (2000) [C1]
|
||||||||||
2000 |
Gardiner BS, Dlugogorski BZ, Jameson GJ, 'Coarsening of two and three dimensional wet polydisperse foams', Phil. Mag. A, 80 (4) 981-1000 (2000) [C1]
|
||||||||||
2000 |
Farmer AD, Collings AF, Jameson GJ, 'Effect of ultrasound on surface cleaning of silica particles', Int. J. Mineral Processing, 60 101-113 (2000) [C1]
|
||||||||||
2000 |
Gardiner BS, Dlugogorski BZ, Jameson GJ, 'The steady shear of three-dimensional wet polydisperse foams', J. Non-Newt. Fluid Mech., 92 151-166 (2000) [C1]
|
||||||||||
2000 |
Magrabi SA, Dlugogorski BZ, Jameson GJ, 'The performance of aged aqueous foams for mitigation of thermal radiation', Dev.Chem.Eng.Mineral Process, 8 93-112 (2000) [C1]
|
||||||||||
2000 |
Biggs S, Habgood MG, Jameson GJ, Yan Y, 'Aggregate structures formed via a bridging flocculation mechanism', Chemical Engineering Journal, 80 13-22 (2000) [C1]
|
||||||||||
2000 |
Glover SM, Yan Y, Jameson GJ, Biggs S, 'Bridging flocculation studied by light scattering and settling', Chemical Engineering Journal, 80 3-12 (2000) [C1]
|
||||||||||
2000 |
Yan Y, Burns JL, Jameson GJ, Biggs S, 'The structure and strength of depletion-force induced particle aggregates', Chemical Engineering Journal, 80 23-30 (2000) [C1]
|
||||||||||
2000 |
Biggs S, Burns JL, Yan Y, Jameson GJ, Jenkins P, 'Molecular weight dependence of the depletion interaction between silica surfaces in solutions of sodium poly(styrene sulfonate)', Langmuir, 16 9242-9248 (2000) [C1]
|
||||||||||
2000 |
Nguyen AV, Evans GM, Jameson GJ, 'Erratum: Simple approximate expressions for electrical double-layer interaction at constant moderate potentials (Journal of Colloid and Interface Science (2000) 1:230 (205-209))', Journal of Colloid and Interface Science, 232 414 (2000)
|
||||||||||
1999 |
Magrabi SA, Dlugogorski BZ, Jameson GJ, 'Bubble size distribution and coarsening of aqueous foams', Chemical Engineering Science, 54 4007-4022 (1999) [C1]
|
||||||||||
1999 |
Gardiner BS, Dlugogorski BZ, Jameson GJ, 'Prediction of pressure losses in pipe flow of aqueous foams', Industrial & Engineering Chemistry Research, 38 1099-1106 (1999) [C1]
|
||||||||||
1999 |
Bremmell KE, Jameson GJ, Biggs S, 'Adsorption of ionic surfactants in particulate systems: flotation, stability, and interaction forces', Colloids and Surfaces, 146 75-87 (1999) [C1]
|
||||||||||
1999 |
Burns JL, Yan Y, Jameson GJ, Biggs S, 'Relationship between interaction forces and the structural compactness of depletion flocculated colloids', Colloids and Surfaces, 162 265-277 (1999) [C1]
|
||||||||||
1999 |
Bremmell KE, Jameson GJ, Biggs S, 'Forces between surfaces in the presence of a cationic polyelectrolyte and an anionic surfactant', Colloids and Surfaces, 155 1-10 (1999) [C1]
|
||||||||||
1999 |
Jameson GJ, 'Hydrophobicity and floc density in induced-air flotation for water treatment', Colloids and Surfaces A, 151 269-281 (1999) [C1]
|
||||||||||
1999 |
Gardiner BS, Dlugogorski BZ, Jameson GJ, 'The evolution of defects in a two-dimensional wet foam', J.Phys:Condens.Matter, 11 5437-5453 (1999) [C1]
|
||||||||||
1998 |
Gardiner BS, Dlugogorski BZ, Jameson GJ, 'Rheology of Fire-Fighting Foams', Fire Safety Journal, 31 61-75 (1998) [C1]
|
||||||||||
1998 |
Gardiner BS, Dlugogorski BZ, Jameson GJ, Chhabra RP, 'Yield Stress Measurements of Aqueous Foams in the Dry Limit', J.Rheology, 42(6) 1437-1450 (1998) [C1]
|
||||||||||
1998 |
Jones SFD, Galvin KP, Evans GM, Jameson GJ, 'Carbonated Water: The Physics of the Cycle of Bubble Production', Chemical Engineering Science, 53, No.1 169-173 (1998) [C3]
|
||||||||||
1998 |
Bremmell KE, Jameson GJ, Biggs S, 'Polyelectrolyte Adsorption at the Solid/Liquid Interface Interaction Forces and Stability', Colloids and Surfaces, 139 199-211 (1998) [C1]
|
||||||||||
1998 |
Jameson GJ, 'New Technology and Science in Flotation Separations', Current Opinion in Colloid & Interface Science, 3 351-359 (1998) [C1]
|
||||||||||
1998 |
Burns JL, Yan Y, Jameson GJ, Biggs S, 'A Comparison of the Fractal Properties of Salt-Aggregated and Polymer-Flocculated Colloidal Particles', Progr Colloid Polymer Science, 110 70-75 (1998) [C1]
|
||||||||||
Show 166 more journal articles |
Conference (106 outputs)
Year | Citation | Altmetrics | Link | ||||||||
---|---|---|---|---|---|---|---|---|---|---|---|
2021 |
Hoque M, Mitra S, Moreno-Atanasio R, Doroodchi E, Evans G, Jameson G, 'Behaviour of coarse particles attached to a bubble within a rotating liquid flow field inside a confined cavity', IMPC 2020 XXX International Mineral Processing Congress, Cape Town, South Africa (2021) [E1]
|
Nova | |||||||||
2019 |
Hoque M, Evans G, Mitra S, Moreno-Atanasio R, Jameson G, 'Numerical analysis of cavity channel flow in absence and presence of a single bubble', Proceedings of 13th International Conference on Mechanical Engineering (ICME 2019), Dhaka, Bangladesh (2019) [E1]
|
Nova | |||||||||
2016 |
Wang G, Evans GM, Jameson GJ, 'Experiments on the detachment of particles from bubbles in a rotating turbulent field', IMPC 2016 - 28th International Mineral Processing Congress (2016) In this paper we present a new method for studying the detachment of particles from bubbles in a rotating turbulent eddy. The eddy is formed in a wall cavity in a two-dimensional ... [more] In this paper we present a new method for studying the detachment of particles from bubbles in a rotating turbulent eddy. The eddy is formed in a wall cavity in a two-dimensional water tunnel with transparent walls. When water flows through the tunnel, a vortical flow field develops in the cavity. The properties of the eddy can be modulated by changing the free-stream velocity of the water in the tunnel. Bubbles are pre-loaded with one or more particles in a fluidized bed flotation device located beneath the vortex cavity. Loaded bubbles are released one at a time into the cavity, and the motion of the bubble-particle aggregate is studied using a high-speed video camera. The diameters of the particles and the bubbles, and the number of particles initially attached to the bubble, can be varied. The trajectories taken by the bubbles are quite complicated. In some cases, the bubble moves to the centre of the eddy, and particles rotate around its axis. If the rotational speed is sufficient, particles may detach due to centrifugal force. However, other modes were observed, including inertial detachment due to rapid changes in direction of the surface of the bubble, because of changes in trajectory of the bubble as a whole, or because of pulsations and oscillations of the bubble surface. Clusters of bubbles held together by particles were seen to form and reform. In the traditional explanation for the detachment of particles in flotation cells, it is assumed that particles detach from bubbles rotating in an eddy due to centrifugal force (Schulze, 1977). Although the conditions assumed in Schulze's theory may exist, it is only one of a range of phenomena that can lead to the detachment of particles from bubbles in a turbulent vortex.
|
||||||||||
2015 |
Wang G, Joshi JB, Sathe M, Jameson GJ, Zhou S, Evans GM, 'Bubble detachment from a steel ball in turbulent field: Application to mineral flotation systems', Procedia Engineering (2015) [E1] Coarse particle (typically more than 100 micrometers in diameter) flotation is adversely influenced by liquid motion resulting from energy input associated with mixing of the gas ... [more] Coarse particle (typically more than 100 micrometers in diameter) flotation is adversely influenced by liquid motion resulting from energy input associated with mixing of the gas and solid phases. In particular, the collected particles can become detached from the bubble as the particle-bubble aggregate passes through regions of different turbulent levels. The dynamics of particle-bubble-turbulence interaction is almost impossible to visualize within a real flotation environment as the phases are in constant motion which changes with time and position. To study the phenomenon of the particle bubble detachment process the problem was mimicked in such a way as to have a bubble detaching from a stationary 3 mm diameter steel particle in the turbulent field. A bubble of known volume was firstly introduced onto the submerged particle surface via a syringe needle. Image analysis was used to determine the bubble-particle contact angle and radial position of the three phase contact line under quiescent conditions. An oscillating grid device was then used to generate turbulent liquid motion around the particle-bubble aggregate. Particle image velocimetry (PIV) was used to quantify the instantaneous velocity field around the disturbed bubble. Laser induced-fluorescence (LIF) was applied to filter out the (green) internally reflected light from the bubble so that only the (orange) light from the fluorescing seeding particles was collected. The PIV-LIF images were then analysed by firstly utilising a masking technique to eliminate spurious velocity vectors inside the bubble. The velocity data in an envelope surrounding the bubble was extracted to calculate local, instantaneous values of liquid velocity, turbulent kinetic energy and energy dissipation rate. It was found that the flow structures generated by the oscillating grids resulted in a lateral inclination of the gas-liquid interface at the three phase contact line. The subsequent change in the dynamic contact angle resulted in a reduction in the capillary (attachment) force, and at a high enough turbulence level it became less than the buoyancy (lift-off) force and detachment of the bubble from the particle surface took place. The detachment events observed in this study is analogous to what actually takes place in mineral flotation cells where the bubble-particle aggregate is in motion.
|
Nova | |||||||||
2014 |
Jameson GJ, 'Experiments on the flotation of coarse composite particles', IMPC 2014 - 27th International Mineral Processing Congress (2014) [E1] When mineral particles are floated in a mechanical flotation cell, it is found that the rate constant, after reaching a maximum value, starts to decline as particle size increases... [more] When mineral particles are floated in a mechanical flotation cell, it is found that the rate constant, after reaching a maximum value, starts to decline as particle size increases. It had been thought that the reduction in rate constant had been due to the increased prevalence of composite particles in natural ores, for larger particles. However, Jameson (2012) showed that the rate constant for composites is certainly a function of the surface liberation, but the reduction in flotation rate is independent of particle size. Thus all particles are equally affected by reduced surface liberation, independently of their size. He further argued that the classical peak observed in the rate constant with increasing particle size, is a function of machine hydrodynamics. Thus in mechanical cells, the peak may be due to the high energy dissipation rate and its effects on the detachment of particles from bubbles (Goel and Jameson, 2012). Consequently, in a different flotation environment, it may be possible to float large composite particles that cannot be floated in mechanical cells. This paper describes the flotation of large composite particles in a fluidized bed flotation cell. The particles to be floated are fed to a column in which there is a continuous upflow of liquid. A conventional froth layer of controlled depth is formed at the top of the vessel. A fluidized bed of particles is established which provides a gentle environment for the contacting of large particles with bubbles. An example is given where a porphyry copper ore was prepared at a top size of 710 µm, and floated with conventional collector (PAX) and frother (MIBC). The concentrate was separated into size fractions and examined by photography. Composites were observed at all size fractions, but above 400 µm, all particles were composites. The implications for future flotation circuits will be described.
|
Nova | |||||||||
2014 | Jameson GJ, 'Reducing whole of enterprise running costs through coarse particle flotation', XXVII International Mineral Processing Congress Proceedings, Santiago, Chile (2014) [E1] | ||||||||||
2014 | Jameson GJ, Rahman R, Ata S, 'Study of froth recovery and froth dropback behaviour in a controlled plant environment', XXVII International Mineral Processing Congress Proceedings, Santiago, Chile (2014) [E1] | Nova | |||||||||
2014 | Bournival G, Jameson GJ, Ata S, 'Influence of additives on gas holdup and bubble size', XXVII International Mineral Processing Congress Proceedings, Santiago, Chile (2014) [E1] | Nova | |||||||||
2014 | Emer C, Bournival G, Jameson GJ, Ata S, 'The use of esterification to create hydrophobic quartz particles for flotation', XXVII International Mineral Processing Congress Proceedings, Santiago, Chile (2014) [E1] | Nova | |||||||||
2013 |
Wang G, Sathe M, Mitra S, Joshi J, Jameson G, Evans GM, 'Influence of grid-generated turbulence on detachment of a bubble anchored to a vertical cylindrical surface: Application to mineral flotation systems', Proceedings. Chemeca 2013, Brisbane, Queensland, Australia (2013) [E1]
|
Nova | |||||||||
2012 |
Rahman RM, Ata S, Jameson GJ, 'Froth recovery measurements in an industrial flotation cell', 26th International Mineral Processing Congress, IMPC 2012: Innovative Processing for Sustainable Growth - Conference Proceedings, New Delhi, India (2012) [E1]
|
Nova | |||||||||
2011 | Moberg AK, Ellem GK, Jameson GJ, Herbertson JG, 'Process engineering in the design of a microalgae photobioreactor', 4th Congress of the International Society for Applied Psychology. Program and Abstracts, Halifax, Canada (2011) [E3] | ||||||||||
2011 |
Neville FC, Murphy TI, Webber GB, Wanless EJ, Jameson GJ, 'Fabrication and characterisation of biomimetic silicate nanoparticles', Chemeca 2011: Engineering a Better World, Sydney (2011) [E1]
|
Nova | |||||||||
2011 | Moberg AK, Ellem GK, Jameson GJ, Herbertson JG, 'Radial mixing within a microalgae photobioreactor', Chemeca 2011: Engineering a Better World, Sydney, NSW (2011) [E1] | ||||||||||
2011 |
Jameson GJ, Goel S, 'New approaches to particle attachment and detachment in flotation', Separation Technologies for Minerals, Coal and Earth Resources, Denver, Colorado (2011) [E1]
|
||||||||||
2010 | Moberg AK, Ellem GK, Jameson GJ, Herbertson JG, 'Process engineering fundamentals in the design of a high performance photobioreactor', Proceedings of the 8th European Workshop on Biotechnology of Microalgae, Nuthetal, Germany (2010) [E3] | ||||||||||
2010 | Goel S, Jameson GJ, 'An experimental study of the behavior of bubble -particle aggregates in turbulent mixing', 19th International Congress of Chemical and Process Engineering, 7th European Congress of Chemical Engineering ECCE-7. Abstracts, Prague, Czech Republic (2010) [E3] | ||||||||||
2010 | Moberg AK, Ellem GK, Jameson GJ, Herbertson JG, 'Process engineering in the design of a high performance photobireactor', Proceedings of the Bioenergy Australia 2010 Conference:, Manly, NSW (2010) [E3] | ||||||||||
2010 | Moberg AK, Ellem GK, Jameson GJ, Herbertson JG, 'Fluid dynamical considerations in the design of a microalgae photobioreactor', Chemeca 2010: Proceedings of the 40th Australasian Chemical Engineering Conference, Adelaide, Australia (2010) [E1] | Nova | |||||||||
2010 |
Nicholson K, Ireland PM, Wanless EJ, Jameson GJ, 'Triboelectric separation - Beneficiation of coal', Congress Proceedings: XXV International Mineral Processing Congress, Brisbane, QLD (2010) [E1]
|
Nova | |||||||||
2010 |
Goel S, Jameson GJ, 'Detachment of particles from bubbles in a stirred cell', Congress Proceedings: XXV International Mineral Processing Congress, Brisbane, QLD (2010) [E1]
|
Nova | |||||||||
2010 |
Ireland PM, Jameson GJ, 'Particle mechanics and the design of cyclone tribochargers', Congress proceedings: XXV International Mineral Processing Congress., Brisbane, QLD (2010) [E1]
|
Nova | |||||||||
2010 |
Chen Z, Ata S, Jameson GJ, 'Behaviour of bubble clusters in a turbulent flow', XXV International Mineral Processing Congress IMPC 2010,, Brisbane (2010) [E1]
|
Nova | |||||||||
2010 |
Rahman R, Ata S, Jameson GJ, 'Development of a froth dropback measurement device', XXV International Mineral Processing Congress IMPC 2010,, Brisbane (2010) [E1]
|
Nova | |||||||||
2009 | Moberg AK, Ellem G, Jameson GJ, Herbertson J, 'Mass transfer of photosynthetic gases within a multiphase microalgae production system', CHEMECA 2009: Engineering Our Future: Are We Up to the Challenge?: CD with Proceedings, Perth, WA (2009) [E1] | Nova | |||||||||
2008 |
Ata S, Pugh RJ, Jameson GJ, 'The influence of coverage of particles on the coalescence of bubbles', 17th International Symposium on Surfactants in Solution. Abstracts, Berlin, Germany (2008) [E3]
|
||||||||||
2008 |
Nicholson K, Ireland PM, Wanless EJ, Jameson GJ, 'Design and construction of a laboratory scale cyclone tribocharger', Chemeca2008, Newcastle, NSW (2008) [E1]
|
Nova | |||||||||
2008 |
Ata S, Jameson GJ, 'Coalescence of bubble pairs in surfactant solutions', Proceedings of XXIV International Mineral Processing Congress, Beijing, China (2008) [E1]
|
Nova | |||||||||
2008 | Yates PD, Franks GV, Jameson GJ, 'Othokinetic heteroaggregation: Effect of particle size ratio on aggregate properties', 22nd Conference of the European Colloid and Interface Society: Book of Abstracts, Kracow, Poland (2008) [E3] | ||||||||||
2007 | Button E, Sader J, Jameson GJ, 'Dynamics of water bells formed on the underside of a horizontal plate', APS Meetings Abstracts, Salt Lake City, Utah (2007) [E3] | ||||||||||
2007 | Euston JA, Atkinson BA, Jameson GJ, 'The recovery of coarse coal particles by flotation in the froth phase', Proceedings of the Eleventh Australian Coal Preparation Conference, Twin Waters, QLD (2007) [E2] | ||||||||||
2006 |
Ata S, Jameson GJ, 'Flotation of Dispersed Silica Particles', Proceedings of XXIII International Mineral Processing Congress, Istanbul, Turkey (2006) [E1]
|
||||||||||
2006 | George PF, Nguyen AV, Jameson GJ, 'Computational Modelling and Validation of Ultrafine Particle Flotation', Proceedings, Fifth International Conference on CFD in the Process Industries, Melbourne (2006) [E1] | ||||||||||
2006 | Jameson GJ, Parekh VV, 'Effect of n-Alcohols on the Rate of Coalescence of Bubbles', 45th International Conference of Metallurgists, COM2006, Montreal, Canada (2006) [E1] | ||||||||||
2006 |
Nguyen AV, Karakashev SI, Jameson GJ, 'Effect of Interfacial Properties on Water Drainage and Recovery in a Froth Column', Proceedings of XXIII International Mineral Processing Congress, Istanbul, Turkey (2006) [E1]
|
||||||||||
2005 | Alexandrova L, Nguyen AV, Grigorov L, Jameson GJ, 'Dewetting Kinetics on Silica Substrates - Three-Phase Cotact Expansion Measurements for Aqueous Dodecylammonium Chloride Films', Centenary of Flotation Symposium, Brisbane (2005) [E1] | ||||||||||
2005 |
Ata S, Agarwal A, Jameson GJ, 'The Formation of Bubble Clusters in Flotation Cells - Effect of Impeller Speed', Centenary of Flotation Symposium, Brisbane (2005) [E1]
|
||||||||||
2005 |
Ata S, Pigram SM, Jameson GJ, 'Tracking of Particles in the Froth Phase - An Experimental Technique', Centenary of Flotation Symposium, Brisbane (2005) [E1]
|
||||||||||
2005 | Jameson GJ, 'Centenary of Flotation Symposium', Centenary of Flotation Symposium, Brisbane (2005) [E4] | ||||||||||
2005 | Jameson GJ, 'Flotation of Coarse and Ultrafine Particles', Centenary of Flotation Symposium, Brisbane (2005) [E1] | ||||||||||
2004 | George PF, Nguyen AV, Jameson GJ, 'Experimental Validation of a Model For Nanoparticle Flotation', 32nd Australasian Chemical Engineering Conference, Sydney (2004) [E1] | ||||||||||
2003 |
Harvey PA, Nguyen AV, Jameson GJ, Evans GM, 'Influence of Surfactants on Foam Stability', The 31st Australasian Chemical Engineering Conference, Adelaide, S.A. (2003) [E1]
|
||||||||||
2003 |
Ata S, Ahmed N, Jameson GJ, 'Gangue Drainage in Flotation Froths', XXII International Mineral Processing Congress, Cape Town, South Africa (2003) [E1]
|
||||||||||
2003 |
Nguyen AV, Harvey PA, Evans GM, Jameson GJ, 'Coal Flotation in Electrolyte Solutions', XXII International Mineral Processing Congress, Cape Town, South Africa (2003) [E1]
|
||||||||||
2002 | Lambert NWA, Jameson GJ, 'Coarse Coal Flotation', Proceedings of the Ninth Australian Coal Preparation Conference, Yeppoon (2002) [E1] | ||||||||||
2002 | Lambert NWA, Jameson GJ, Atkinson BW, 'Full-scale application of wash-water to mechanical flotation cells', Proceedings of the Ninth Australian Coal Preparation Conference, Yeppoon (2002) [E1] | ||||||||||
2002 | Harvey PA, Nguyen AV, Jameson GJ, 'Influence of gas flow rate and surfactants on liquid drainage in flotation froth and foam', Proceedings, APCChE Congress and CHEMECA 2002, New Zealand (2002) [E1] | ||||||||||
2002 | Franks GV, Weseloh S, Idewaputo W, Yan Y, Jameson GJ, 'Controlling size and structure of particle aggregatesby solids concentration and shear', Proceedings, World Congress on Particle Technology 4, Sydney (2002) [E1] | ||||||||||
2002 | Olsen AH, Yan Y, Glover SM, Jameson GJ, Biggs S, 'Effect of shear rate on flocculation efficiency of polymeric flocculants', Proceedings, World Congress on Particle Technology 4, Sydney (2002) [E1] | ||||||||||
2002 | Yan Y, Glover SM, Jameson GJ, Biggs S, 'Effect of polymer molecular weight distribution on particle flocculation', Proceedings, World Congress on Particle Technology 4, Sydney (2002) [E1] | ||||||||||
2002 | Yates PD, Yan Y, Jameson GJ, Biggs S, 'Effect of flocculant flexibility in bridging flocculation', Proceedings, World Congress on Particle Technology 4, Sydney (2002) [E1] | ||||||||||
2001 | Franks GV, Yan Y, Olsen AH, Hogg B, Biggs S, Jameson GJ, 'Relationship between aggregate properties and the rheological behaviour of sediment beds', Proceedings, 6th World Congress of Chemical Engineering, Melbourne, Australia (2001) [E1] | ||||||||||
2001 |
Nguyen AV, Evans GM, Jameson GJ, 'Bubble-particle attachment interaction in froth flotation', Proceedings, 6th World Congress of Chemical Engineering, Melbourne, Australia (2001) [E1]
|
||||||||||
2001 | Yates PD, Yan Y, Jameson GJ, Biggs S, 'Hetercoagulation of particle systems: aggregation mechanism and aggregate structure determination', Proceedings, 6th World Congress of Chemical Engineering, Melbourne, Australia (2001) [E1] | ||||||||||
2001 | Yates PD, Yan Y, Jameson GJ, Biggs S, 'Bridging flocculation mechanisms: the role of chain flexibility', Proceedings, 6th World Congress of Chemical Engineering, Melbourne, Austrlia (2001) [E1] | ||||||||||
2001 | Glover SM, Yan Y, Jameson GJ, Biggs S, 'Polymer molecular weight and mixing effects on floc compressibiity and filterability', Proceedings, 6th World Congress of Chemical Engineering, Melbourne, Australia (2001) [E1] | ||||||||||
2001 | Franks GV, Yates PD, Lambert NWA, Jameson GJ, 'Shear Resistant aggregates for hydrocyclone thckening of fine coal tailings', Eighteenth Annual International Pittsburgh Coal Conference Proceedings, Newcastle, Australia (2001) [E2] | ||||||||||
2001 | Lambert N, Jameson GJ, 'Coarse coal flotation', Eighteenth Annual International Pittsburgh Coal Conference Proceedings, Newcastle, Australia (2001) [E2] | ||||||||||
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]
|
||||||||||
2001 |
Evans GM, Manning SA, Jameson GJ, 'Cavity formation, growth and dispersion behind rotating impeller blades', 4th International Symposium on Mixing in Industrial Processes, Toulouse, France (2001) [E1]
|
||||||||||
2000 |
Farmer AD, Collings AF, Jameson GJ, 'The application of power ultrasound to the surface cleaning of silica and heavy mineral sands', ULTRASONICS SONOCHEMISTRY, TOULOUSE, FRANCE (2000)
|
||||||||||
2000 | Glover SM, Yan Y, Jameson GJ, 'Aggregation mechanisms of the primary stage in a dual-polymer flocculation process', 28th Australasian Chemical Engineering Conference, Perth, WA (2000) [E1] | ||||||||||
2000 | Perry DC, Jameson GJ, 'The use of carbon dioxide monitoring to measure activity in biological processing', 28th Australasian Chemical Engineering Conference, Perth, WA (2000) [E1] | ||||||||||
2000 | Perry DC, Jameson GJ, 'Thermophilic treatment of organic waste', 28th Australasian Chemical Engineering Conference, Perth, WA (2000) [E1] | ||||||||||
2000 | Franks GV, Marechal PS, Jameson GJ, 'Effect of monovalent salt type on the zeta potentials of alkane particles', Proceedings of the 28th Australasian Chemical Engineering Conference, (Chemeca 2000), Perth WA (2000) [E1] | ||||||||||
1999 | Burns JL, Yan Y, Jameson GJ, Biggs S, 'Solids consolidation using polymer-induced depletion forces', 27th Australasian Chemical Engineering Conference, Newcastle (1999) [E1] | ||||||||||
1999 | Glover SM, Yan Y, Jameson GJ, Biggs S, 'Characterisation of the structural compactness of bridging flocculated aggregates using settling', 27th Australasian Chemical Engineering Conference, Newcastle (1999) [E1] | ||||||||||
1999 | Magrabi SA, Dlugogorski BZ, Jameson GJ, 'The effect of bubble morphology and liquid holdup on the radiation attenuation properties of fire fighting foams', 27th Australasian Chemical Engineering Conference, Newcastle (1999) [E1] | ||||||||||
1999 | Yan Y, Jameson GJ, 'Simultaneous algae and phosphorus removal from wastewaters using induced air flotation', 27th Australasian Chemical Engineering Conference, Newcastle (1999) [E1] | ||||||||||
1999 | Magrabi SA, Dlugogorski BZ, Jameson GJ, 'A model for foam drainage', 27th Australasian Chemical Engineering Conference, Newcastle (1999) [E1] | ||||||||||
1999 | Bremmell KE, Biggs S, Jameson GJ, 'Polyelectrolyte/surfactant interactions in particulate flotation', Polymers in Mineral Processing, Montreal (1999) [E1] | ||||||||||
1998 | Gardiner BS, Dlugogorski BZ, Jameson GJ, Chhabra RP, 'Yield Stress of Firefighting Foams', Proceedings, Halon Options Technical Working Conference, Albuquerque, New Mexico (1998) [E2] | ||||||||||
1998 |
Drewer GR, Ahmed N, Jameson GJ, 'An Optimum Concentration for the Suspension of Solids in Stirred Vessels', International Conference on Mixing and Crystallization, Tioman Island, Malaysia (1998) [E2]
|
||||||||||
1998 |
Evans GM, Mao W, Jameson GJ, 'Mass Transfer in a Plunging Liquid Jet', International Conference on Mixing and Crystallization, Tioman Island, Malaysia (1998) [E2]
|
||||||||||
1998 | Farmer AD, Collings AF, Jameson GJ, 'Ultrasonic Processing of Silica and Heavy Mineral Sands', Proceedings of the 26th Australasian Chemical Engineering Conference, Port Douglas, Australia (1998) [E1] | ||||||||||
1998 | Magrabi SA, Dlugogorski BZ, Jameson GJ, 'Model Predictions of Bubble Coarsening in Fire-Fighting Foams Generated with Inert Gases and Clean Gaseous Agents', Proceedings of the 26th Australasian Chemical Engineering Conference, Port Douglas, Australia (1998) [E1] | ||||||||||
1998 | Yan Y, Burns JL, Jameson GJ, Biggs S, 'The Fractal Properties of Latex Particle Aggregates Formed in the Presence of Salt and Non-Adsorbing Polymer', Proceedings of the 26th Australasian Chemical Engineering Conference, Port Douglas, Australia (1998) [E1] | ||||||||||
1998 | Biggs S, Habgood M, Jameson GJ, Yan Y, 'The Fractal Analysis of Aggregates Formed via a Bridging Flocculation Mechanism', Proceedings of the 26th Australasian Chemical Engineering Conference, Port Douglas, Australia (1998) [E1] | ||||||||||
1998 | Magrabi SA, Dlugogorski BZ, Jameson GJ, 'Effect of Aging on the Absorption of Thermal Radiation by Aqueous Foam', Proceedings, Fire & Explosion Hazard of Subdstances and Venting of Deflagration: 2nd International Seminar, Moscow, Russia (1998) [E2] | ||||||||||
1998 | Burns JL, Yan Y, Jameson GJ, Biggs S, 'Fractal Analysis of Flocculation in a Latex Dispersion Induced by Non-Adsorbing Polymer', World Congress on Particle Technology 3, Brighton, U.K. (1998) [E1] | ||||||||||
Show 103 more conferences |
Patent (4 outputs)
Year | Citation | Altmetrics | Link |
---|---|---|---|
2006 | Jameson GJ, Method and Apparatus for Froth Washing in Flotation (2006) [I3] | ||
2006 | Jameson GJ, Method and Apparatus for Contacting Bubbles and Particles in a Flotation Separation System (2006) [I3] | ||
2005 | Franks GV, Jameson GJ, Yan Y, Biggs SR, Stimulant sensitive flocculation and consolidation (2005) [I2] | Nova | |
2004 | Jameson GJ, Lambert N, Improved froth flotation process and apparatus (2004) [I1] | ||
Show 1 more patent |
Grants and Funding
Summary
Number of grants | 69 |
---|---|
Total funding | $60,741,137 |
Click on a grant title below to expand the full details for that specific grant.
20236 grants / $555,211
4D Tomographic Particle Image Velocimetry for Multiphase Flow Measurement$393,481
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Associate Professor Elham Doroodchi, Laureate Professor Kevin Galvin, Emeritus Professor Graeme Jameson, Doctor Zhengbiao Peng, Doctor Subhasish Mitra, Seher Ata, Associate Professor Seher Ata, Associate Professor John Kavanagh, John Kavanagh |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) |
Role | Investigator |
Funding Start | 2023 |
Funding Finish | 2023 |
GNo | G2200633 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
3D particle surface composition analysis for flotation using microCT$81,730
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Doctor Rohan Stanger, Bruce Atkinson, Emeritus Professor Graeme Jameson |
Scheme | Australian Coal Association Research Program (ACARP) |
Role | Investigator |
Funding Start | 2023 |
Funding Finish | 2024 |
GNo | G2300969 |
Type Of Funding | C1700 - Aust Competitive - Other |
Category | 1700 |
UON | Y |
4D Tomographic Particle Image Velocimetry for Multiphase Flow Measurement$40,000
Funding body: FLSmidth & Co. A/S
Funding body | FLSmidth & Co. A/S |
---|---|
Project Team | Associate Professor Elham Doroodchi, Associate Professor Seher Ata, Laureate Professor Kevin Galvin, Emeritus Professor Graeme Jameson, Associate Professor John Kavanagh, Doctor Subhasish Mitra, Doctor Zhengbiao Peng |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) Partner Funding |
Role | Investigator |
Funding Start | 2023 |
Funding Finish | 2023 |
GNo | G2300389 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
4D Tomographic Particle Image Velocimetry for Multiphase Flow Measurement$20,000
Funding body: University of Sydney
Funding body | University of Sydney |
---|---|
Project Team | Associate Professor Elham Doroodchi, Associate Professor Seher Ata, Laureate Professor Kevin Galvin, Emeritus Professor Graeme Jameson, Associate Professor John Kavanagh, Doctor Subhasish Mitra, Doctor Zhengbiao Peng |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) Partner Funding |
Role | Investigator |
Funding Start | 2023 |
Funding Finish | 2023 |
GNo | G2300386 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
4D Tomographic Particle Image Velocimetry for Multiphase Flow Measurement$10,000
Funding body: University of New South Wales
Funding body | University of New South Wales |
---|---|
Project Team | Associate Professor Elham Doroodchi, Associate Professor Seher Ata, Laureate Professor Kevin Galvin, Emeritus Professor Graeme Jameson, Associate Professor John Kavanagh, Doctor Subhasish Mitra, Doctor Zhengbiao Peng |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) Partner Funding |
Role | Investigator |
Funding Start | 2023 |
Funding Finish | 2023 |
GNo | G2300388 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
4D Tomographic Particle Image Velocimetry for Multiphase Flow Measurement$10,000
Funding body: Hunter Water Corporation
Funding body | Hunter Water Corporation |
---|---|
Project Team | Associate Professor Elham Doroodchi, Associate Professor Seher Ata, Laureate Professor Kevin Galvin, Emeritus Professor Graeme Jameson, Associate Professor John Kavanagh, Doctor Subhasish Mitra, Doctor Zhengbiao Peng |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) Partner Funding |
Role | Investigator |
Funding Start | 2023 |
Funding Finish | 2023 |
GNo | G2300390 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
20205 grants / $38,109,119
ARC Centre of Excellence for Enabling Eco-Efficient Beneficiation of Minerals$35,911,119
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Kevin Galvin, Doctor Subhasish Mitra, Professor San Thang, Professor Karen Hapgood, Professor Erica Wanless, Emeritus Professor Graeme Jameson, Professor Geoffrey Evans, A/Prof Chun-Xia Zhao, Professor Grant Webber, Prof Bill Skinner, Associate Professor George Franks, Doctor Roberto Moreno-Atanasio, Associate Professor Elham Doroodchi, Doctor Peter Ireland, Professor Kenneth Williams, Seher Ata, Grant Ballantyne, Associate Professor David Beattie, Susana Brito e Abreu, Professor Robert Davis, Jacobus Eksteen, Elizaveta Forbes, Marta Krasowska, Dr Colin MacRae, Professor Anh Nguyen, Jan Miller, A/Prof Aaron Noble, Yongjun Peng, Kym Runge, Peter Scales, Anthony Stickland, Boon Teo, Nathan Webster, Professor Zhenghe Xu, Professor Steven Armes, Miss Meolla Yvon, Professor Jan Miller, Doctor Mahshid Firouzi, Professor Alister Page, Miss Margaret Ekua Amosah |
Scheme | ARC Centres of Excellence |
Role | Investigator |
Funding Start | 2020 |
Funding Finish | 2026 |
GNo | G1800891 |
Type Of Funding | C1200 - Aust Competitive - ARC |
Category | 1200 |
UON | Y |
ARC Centre of Excellence for Enabling Eco-Efficient Beneficiation of Minerals$1,400,000
Funding body: AMIRA International Limited
Funding body | AMIRA International Limited |
---|---|
Project Team | Laureate Professor Kevin Galvin, Professor San Thang, Professor Karen Hapgood, Emeritus Professor Graeme Jameson, A/Prof Chun-Xia Zhao, Prof Bill Skinner, Associate Professor George Franks, Peter Scales, Professor Erica Wanless, Professor Geoffrey Evans, Professor Anh Nguyen, Associate Professor David Beattie, Jacobus Eksteen, Professor Kenneth Williams, Seher Ata, Professor Grant Webber, Yongjun Peng, Doctor Roberto Moreno-Atanasio, Boon Teo, Susana Brito e Abreu, Grant Ballantyne, Marta Krasowska, A/Prof Aaron Noble, Anthony Stickland, Associate Professor Elham Doroodchi, Kym Runge, Nathan Webster, Doctor Peter Ireland, Elizaveta Forbes, Dr Colin MacRae, Professor Steven Armes, Professor Robert Davis, Professor Jan Miller, Professor Zhenghe Xu |
Scheme | Centre of Excellence Partner Funding |
Role | Investigator |
Funding Start | 2020 |
Funding Finish | 2026 |
GNo | G1900996 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
ARC Centre of Excellence for Enabling Eco-Efficient Beneficiation of Minerals$320,000
Funding body: FLSmidth & Co. A/S
Funding body | FLSmidth & Co. A/S |
---|---|
Project Team | Laureate Professor Kevin Galvin, Professor San Thang, Professor Karen Hapgood, Emeritus Professor Graeme Jameson, A/Prof Chun-Xia Zhao, Prof Bill Skinner, Associate Professor George Franks, Professor Jan Miller, Peter Scales, Professor Erica Wanless, Professor Geoffrey Evans, Professor Anh Nguyen, Associate Professor David Beattie, Jacobus Eksteen, Professor Kenneth Williams, Seher Ata, Professor Grant Webber, Yongjun Peng, Doctor Roberto Moreno-Atanasio, Boon Teo, Susana Brito e Abreu, Grant Ballantyne, Marta Krasowska, A/Prof Aaron Noble, Anthony Stickland, Associate Professor Elham Doroodchi, Kym Runge, Nathan Webster, Doctor Peter Ireland, Elizaveta Forbes, Dr Colin MacRae, Professor Steven Armes, Professor Robert Davis, Professor Zhenghe Xu, Mr Naif Raja, Mr Joshua Starrett |
Scheme | Centre of Excellence Partner Funding |
Role | Investigator |
Funding Start | 2020 |
Funding Finish | 2026 |
GNo | G1900997 |
Type Of Funding | C3400 – International For Profit |
Category | 3400 |
UON | Y |
ARC Centre of Excellence for Enabling Eco-Efficient Beneficiation of Minerals$280,000
Funding body: Jord International Pty Limited
Funding body | Jord International Pty Limited |
---|---|
Project Team | Laureate Professor Kevin Galvin, Professor San Thang, Professor Karen Hapgood, Emeritus Professor Graeme Jameson, A/Prof Chun-Xia Zhao, Prof Bill Skinner, Associate Professor George Franks, Professor Jan Miller, Peter Scales, Professor Erica Wanless, Professor Geoffrey Evans, Professor Anh Nguyen, Associate Professor David Beattie, Jacobus Eksteen, Professor Kenneth Williams, Seher Ata, Professor Grant Webber, Yongjun Peng, Doctor Roberto Moreno-Atanasio, Boon Teo, Susana Brito e Abreu, Grant Ballantyne, Marta Krasowska, A/Prof Aaron Noble, Anthony Stickland, Associate Professor Elham Doroodchi, Kym Runge, Nathan Webster, Doctor Peter Ireland, Elizaveta Forbes, Dr Colin MacRae, Professor Steven Armes, Professor Robert Davis, Professor Zhenghe Xu |
Scheme | Centre of Excellence Partner Funding |
Role | Investigator |
Funding Start | 2020 |
Funding Finish | 2026 |
GNo | G1900999 |
Type Of Funding | C3100 – Aust For Profit |
Category | 3100 |
UON | Y |
Froth Flotation of 4mm Feed Coal Particles$198,000
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Australian Coal Association Research Program (ACARP) |
Role | Lead |
Funding Start | 2020 |
Funding Finish | 2021 |
GNo | G2000601 |
Type Of Funding | C1700 - Aust Competitive - Other |
Category | 1700 |
UON | Y |
20191 grants / $568,627
Predicting the recovery of composite mineral particles in froth flotation$568,627
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson, Prof Anh Nguyen |
Scheme | Discovery Projects |
Role | Lead |
Funding Start | 2019 |
Funding Finish | 2021 |
GNo | G1800323 |
Type Of Funding | C1200 - Aust Competitive - ARC |
Category | 1200 |
UON | Y |
20182 grants / $1,065,490
Low emission coal in the manufacture of carbon fibres$717,534
Funding body: NSW Department of Planning, Industry and Environment
Funding body | NSW Department of Planning, Industry and Environment |
---|---|
Project Team | Emeritus Professor Terry Wall, Doctor Rohan Stanger, Emeritus Professor Graeme Jameson, Associate Professor John Lucas, Naebe, Minoo |
Scheme | Coal Innovation NSW Fund |
Role | Investigator |
Funding Start | 2018 |
Funding Finish | 2022 |
GNo | G1800572 |
Type Of Funding | C2300 – Aust StateTerritoryLocal – Own Purpose |
Category | 2300 |
UON | Y |
Tuneable energy dissipation for optimal flotation recovery$347,956
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Professor Geoffrey Evans, Emeritus Professor Graeme Jameson, Doctor Roberto Moreno-Atanasio |
Scheme | Discovery Projects |
Role | Investigator |
Funding Start | 2018 |
Funding Finish | 2020 |
GNo | G1700365 |
Type Of Funding | C1200 - Aust Competitive - ARC |
Category | 1200 |
UON | Y |
20161 grants / $148,169
Coarse particle flotation for the plant of the future$148,169
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Australian Coal Association Research Program (ACARP) |
Role | Lead |
Funding Start | 2016 |
Funding Finish | 2017 |
GNo | G1600150 |
Type Of Funding | Aust Competitive - Non Commonwealth |
Category | 1NS |
UON | Y |
20141 grants / $1,242,147
Flotation of composite particles$1,242,147
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Discovery Projects |
Role | Lead |
Funding Start | 2014 |
Funding Finish | 2016 |
GNo | G1300451 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
20122 grants / $55,000
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 |
3D Gamma Ray Tomography for Multiphase Flow Characterisation$20,000
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Dr Vishnu Pareek, Professor Geoffrey Evans, Associate Professor Elham Doroodchi, Doctor Roberto Moreno-Atanasio, Emeritus Professor Graeme Jameson |
Scheme | Equipment Grant |
Role | Investigator |
Funding Start | 2012 |
Funding Finish | 2012 |
GNo | G1100626 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
20116 grants / $1,075,000
A high-rate process for mineral flotation$750,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Discovery Projects |
Role | Lead |
Funding Start | 2011 |
Funding Finish | 2013 |
GNo | G1000231 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Interfacial Mapping Facility$180,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Professor Paul Dastoor, Emeritus Professor Graeme Jameson, Professor Erica Wanless, Professor Grant Webber, Conjoint Professor Rob Atkin, Professor Ewa Goldys, Professor Deborah Kane, Dr James Downes, Dr Gregory Wilson, Doctor Chris Fell |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) |
Role | Investigator |
Funding Start | 2011 |
Funding Finish | 2011 |
GNo | G1000635 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
Advanced Multiphase Flow Characterization Facility$50,000
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Dr Vishnu Pareek, Professor Geoffrey Evans, Professor Dongke Zhang, Assoc. Prof Aibing Yu, Professor Moses Tade, Dr Ranjeet Utikar, Emeritus Professor Graeme Jameson, Laureate Professor Kevin Galvin, Associate Professor Elham Doroodchi |
Scheme | Equipment Grant |
Role | Investigator |
Funding Start | 2011 |
Funding Finish | 2011 |
GNo | G1000460 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
Interfacial Mapping Facility$40,000
Funding body: CSIRO - Commonwealth Scientific and Industrial Research Organisation
Funding body | CSIRO - Commonwealth Scientific and Industrial Research Organisation |
---|---|
Project Team | Professor Paul Dastoor, Emeritus Professor Graeme Jameson, Professor Erica Wanless, Professor Grant Webber, Conjoint Professor Rob Atkin, Professor Ewa Goldys, Professor Deborah Kane, Dr James Downes, Dr Gregory Wilson, Doctor Chris Fell |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) Partner Funding |
Role | Investigator |
Funding Start | 2011 |
Funding Finish | 2011 |
GNo | G1100411 |
Type Of Funding | Other Public Sector - Commonwealth |
Category | 2OPC |
UON | Y |
Interfacial Mapping Facility$30,000
Funding body: Macquarie University
Funding body | Macquarie University |
---|---|
Project Team | Professor Paul Dastoor, Emeritus Professor Graeme Jameson, Professor Erica Wanless, Professor Grant Webber, Conjoint Professor Rob Atkin, Professor Ewa Goldys, Professor Deborah Kane, Dr James Downes, Dr Gregory Wilson, Doctor Chris Fell |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) Partner Funding |
Role | Investigator |
Funding Start | 2011 |
Funding Finish | 2011 |
GNo | G1100872 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
Improving the recovery of coarse particles in flotation$25,000
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Emeritus Professor Graeme Jameson, Doctor Seher Ata |
Scheme | Near Miss Grant |
Role | Lead |
Funding Start | 2011 |
Funding Finish | 2011 |
GNo | G1001040 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
20104 grants / $965,535
High speed Particle Image Velocimetry and Laser-Induced Fluorescence Facility$495,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Professor Geoffrey Evans, Associate Professor Elham Doroodchi, Laureate Professor Kevin Galvin, Emeritus Professor Graeme Jameson, Emeritus Professor Mark Jones, Doctor Paul Stevenson, Professor Anh Nguyen, Professor Victor Rudolph, Dr Liguang Wang, Dr Zhi Ping Xu, Dr Vishnu Pareek, Dr Chi Phan, Professor Moses Tade, Dr Ranjeet Utikar, Assoc. Prof Aibing Yu, Dr Run Yang, Professor John Ralston, Associate Professor Stephen Grano |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) |
Role | Investigator |
Funding Start | 2010 |
Funding Finish | 2010 |
GNo | G0190414 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
High speed Particle Image Velocimetry and Laser-Induced Fluorescence Facility$185,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Professor Geoffrey Evans, Associate Professor Elham Doroodchi, Laureate Professor Kevin Galvin, Emeritus Professor Graeme Jameson, Emeritus Professor Mark Jones, Doctor Paul Stevenson, Professor Anh Nguyen, Professor Victor Rudolph, Dr Liguang Wang, Dr Zhi Ping Xu, Dr Vishnu Pareek, Dr Chi Phan, Professor Moses Tade, Dr Ranjeet Utikar, Assoc. Prof Aibing Yu, Dr Run Yang, Professor John Ralston, Associate Professor Stephen Grano |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) Partner Funding |
Role | Investigator |
Funding Start | 2010 |
Funding Finish | 2010 |
GNo | G1000879 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
High speed Particle Image Velocimetry and Laser-Induced Fluorescence Facility$150,000
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Professor Geoffrey Evans, Associate Professor Elham Doroodchi, Laureate Professor Kevin Galvin, Emeritus Professor Graeme Jameson, Emeritus Professor Mark Jones, Doctor Paul Stevenson, Professor Anh Nguyen, Professor Victor Rudolph, Dr Liguang Wang, Dr Zhi Ping Xu, Dr Vishnu Pareek, Dr Chi Phan, Professor Moses Tade, Dr Ranjeet Utikar, Assoc. Prof Aibing Yu, Dr Run Yang, Professor John Ralston, Associate Professor Stephen Grano |
Scheme | Equipment Grant |
Role | Investigator |
Funding Start | 2010 |
Funding Finish | 2010 |
GNo | G1000875 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
Soft matter and responsive materials characterisation facility$135,535
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Dr Raymond Dagastine, Emeritus Professor Graeme Jameson, Professor Grant Webber, Conjoint Professor Rob Atkin, Professor Erica Wanless |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) |
Role | Lead |
Funding Start | 2010 |
Funding Finish | 2010 |
GNo | G1000397 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
20081 grants / $800,000
New process for mineral flotation$800,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Discovery Projects |
Role | Lead |
Funding Start | 2008 |
Funding Finish | 2010 |
GNo | G0187497 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
20064 grants / $4,461,577
Australian Mineral Science Research Institute (AMSRI)$1,735,290
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Linkage Projects |
Role | Lead |
Funding Start | 2006 |
Funding Finish | 2010 |
GNo | G0186074 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Australian Mineral Science Research Institute (AMSRI)$1,227,005
Funding body: AMIRA International Limited
Funding body | AMIRA International Limited |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Linkage Projects Partner Funding |
Role | Lead |
Funding Start | 2006 |
Funding Finish | 2010 |
GNo | G0186810 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Extending the range of the flotation process for particle separation$950,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson, Doctor Seher Ata |
Scheme | Discovery Projects |
Role | Lead |
Funding Start | 2006 |
Funding Finish | 2010 |
GNo | G0185241 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
PRC - Priority Research Centre for Advanced Particle Processing$549,282
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Laureate Professor Kevin Galvin, Professor Geoffrey Evans, Emeritus Professor Mark Jones, Emeritus Professor Graeme Jameson, Emeritus Professor Alan Roberts, Professor Erica Wanless |
Scheme | Priority Research Centre |
Role | Investigator |
Funding Start | 2006 |
Funding Finish | 2013 |
GNo | G0186920 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
20052 grants / $324,728
Mineral Flotation - Integrating Science and Practice$249,728
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson, Doctor Seher Ata |
Scheme | Linkage Projects |
Role | Lead |
Funding Start | 2005 |
Funding Finish | 2007 |
GNo | G0185579 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
2005 RIBG allocation$75,000
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Research Infrastructure Block Grant (RIBG) |
Role | Lead |
Funding Start | 2005 |
Funding Finish | 2005 |
GNo | G0185784 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
20043 grants / $455,124
Atomic Force Microscopy Facility for Soft Interfaces$445,124
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Associate Professor Anh Nguyen, Emeritus Professor Graeme Jameson, Professor Geoffrey Evans, Associate Professor George Franks, Laureate Professor Kevin Galvin, Professor Erica Wanless, Associate Professor David Smith |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) |
Role | Investigator |
Funding Start | 2004 |
Funding Finish | 2004 |
GNo | G0183028 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
Atomic Force Microscopy Facility for Soft Interfaces$5,000
Funding body: University of New South Wales
Funding body | University of New South Wales |
---|---|
Project Team | Associate Professor Anh Nguyen, Emeritus Professor Graeme Jameson, Professor Geoffrey Evans, Associate Professor George Franks, Laureate Professor Kevin Galvin, Professor Erica Wanless, Associate Professor David Smith |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) Partner Funding |
Role | Investigator |
Funding Start | 2004 |
Funding Finish | 2004 |
GNo | G0183831 |
Type Of Funding | Not Known |
Category | UNKN |
UON | Y |
Atomic Force Microscopy Facility for Soft Interfaces$5,000
Funding body: ORICA Australia Pty Ltd
Funding body | ORICA Australia Pty Ltd |
---|---|
Project Team | Associate Professor Anh Nguyen, Emeritus Professor Graeme Jameson, Professor Geoffrey Evans, Associate Professor George Franks, Professor Erica Wanless, Associate Professor David Smith |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) Partner Funding |
Role | Investigator |
Funding Start | 2004 |
Funding Finish | 2004 |
GNo | G0183832 |
Type Of Funding | Not Known |
Category | UNKN |
UON | Y |
20036 grants / $3,386,766
Centre for Multiphase Processes$1,593,090
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Special Research Centres |
Role | Lead |
Funding Start | 2003 |
Funding Finish | 2005 |
GNo | G0183835 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Flotation separation of nanoparticles$561,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Discovery Projects |
Role | Lead |
Funding Start | 2003 |
Funding Finish | 2006 |
GNo | G0182109 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Integrated Processes for Fine Coal Treatment.$450,000
Funding body: Australian Coal Research Limited
Funding body | Australian Coal Research Limited |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Linkage Projects Partner Funding |
Role | Lead |
Funding Start | 2003 |
Funding Finish | 2005 |
GNo | G0183054 |
Type Of Funding | Contract - Aust Non Government |
Category | 3AFC |
UON | Y |
Integrated processes for fine coal treatment.$368,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Linkage Projects |
Role | Lead |
Funding Start | 2003 |
Funding Finish | 2005 |
GNo | G0182173 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Integrated Facility for Interfacial Rheology Analysis.$260,876
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Associate Professor Anh Nguyen, Professor Geoffrey Evans, Emeritus Professor Graeme Jameson, Professor John Ralston, Professor Geoffrey Stevens, Laureate Professor Kevin Galvin, Professor Simon Biggs, Assoc. Prof D Dunstan, Assoc. Prof D Fornasiero, Associate Professor David Beattie, Conjoint Professor Bogdan Dlugogorski, Associate Professor George Franks |
Scheme | Linkage Infrastructure Equipment & Facilities (LIEF) |
Role | Investigator |
Funding Start | 2003 |
Funding Finish | 2003 |
GNo | G0181893 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
Innovative technologies to reduce water content of dewatered sludges.$153,800
Funding body: CSIRO - Energy Technology
Funding body | CSIRO - Energy Technology |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Research Grant |
Role | Lead |
Funding Start | 2003 |
Funding Finish | 2004 |
GNo | G0183351 |
Type Of Funding | Other Public Sector - Commonwealth |
Category | 2OPC |
UON | Y |
20023 grants / $1,018,076
Behaviour of particles in flotation froths$840,576
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson, Associate Professor Anh Nguyen, Professor J Van Deventer |
Scheme | Discovery Projects |
Role | Lead |
Funding Start | 2002 |
Funding Finish | 2005 |
GNo | G0181081 |
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 | Investigator |
Funding Start | 2002 |
Funding Finish | 2002 |
GNo | G0181517 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
Flotation and Flocculation Hawaii, July 28 - August 2, 2002$2,500
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Travel Grant |
Role | Lead |
Funding Start | 2002 |
Funding Finish | 2002 |
GNo | G0182002 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
20011 grants / $195,000
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 |
20001 grants / $1,770,000
Centre for Multiphase Processes$1,770,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Special Research Centres |
Role | Lead |
Funding Start | 2000 |
Funding Finish | 2002 |
GNo | G0188014 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
19991 grants / $171,688
Hydrophobic attractions and electrostatic repulsions: transitional effects$171,688
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Vincent Craig, Emeritus Professor Graeme Jameson |
Scheme | Australian Postdoctoral Research Fellowship |
Role | Investigator |
Funding Start | 1999 |
Funding Finish | 2002 |
GNo | G0177867 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
19971 grants / $1,950,000
Centre for Multiphase Processes$1,950,000
Funding body: Department of Education, Training & Youth Affairs
Funding body | Department of Education, Training & Youth Affairs |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Special Research Centres |
Role | Lead |
Funding Start | 1997 |
Funding Finish | 1999 |
GNo | G0176999 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
19967 grants / $616,582
Carrying capacity in froth flotation$195,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson, Dr Bruce Atkinson |
Scheme | Strategic Partnerships with Industry - Research & Training Scheme (SPIRT) |
Role | Lead |
Funding Start | 1996 |
Funding Finish | 1998 |
GNo | G0175489 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Carrying capacity in froth flotation. 1996 COLLAB PARTNER.$195,000
Funding body: MIM Exploration Pty Ltd
Funding body | MIM Exploration Pty Ltd |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | SPIRT Partner Funding |
Role | Lead |
Funding Start | 1996 |
Funding Finish | 1998 |
GNo | G0179129 |
Type Of Funding | Donation - Aust Non Government |
Category | 3AFD |
UON | Y |
Topology and stability of 3D cellular foams in motion$160,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Conjoint Professor Bogdan Dlugogorski, Emeritus Professor Graeme Jameson |
Scheme | Large Grant |
Role | Investigator |
Funding Start | 1996 |
Funding Finish | 1998 |
GNo | G0175343 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Interaction Between Surfactants and Polymer Flocculated Solids$22,904
Funding body: Jetflote Pty Ltd
Funding body | Jetflote Pty Ltd |
---|---|
Project Team | Janine Burns, Professor Simon Biggs, Emeritus Professor Graeme Jameson |
Scheme | Research Grant |
Role | Investigator |
Funding Start | 1996 |
Funding Finish | 1999 |
GNo | G0177695 |
Type Of Funding | Contract - Aust Non Government |
Category | 3AFC |
UON | Y |
Particle Recovery Mechanisms in High Intensity Flotation Froths$17,178
Funding body: Australia Council for the Arts
Funding body | Australia Council for the Arts |
---|---|
Project Team | Mr Jose Menendez, Emeritus Professor Graeme Jameson, Professor Geoffrey Evans |
Scheme | Research Fellowship |
Role | Investigator |
Funding Start | 1996 |
Funding Finish | 1998 |
GNo | G0177694 |
Type Of Funding | Other Public Sector - Commonwealth |
Category | 2OPC |
UON | Y |
Heat transfer in cellular materials.$14,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson, Conjoint Professor Bogdan Dlugogorski |
Scheme | Small Grant |
Role | Lead |
Funding Start | 1996 |
Funding Finish | 1996 |
GNo | G0175856 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
Horizontal differnetial migration of spherical particles during sedimentation$12,500
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Kevin Galvin, Emeritus Professor Graeme Jameson |
Scheme | Small Grant |
Role | Investigator |
Funding Start | 1996 |
Funding Finish | 1996 |
GNo | G0175821 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
19954 grants / $553,398
Bubble behaviour in extensional flows.$469,898
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Special Investigator Award |
Role | Lead |
Funding Start | 1995 |
Funding Finish | 1997 |
GNo | G0174560 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Fluid and Particle Technology Research$67,000
Funding body: Department of Education, Training & Youth Affairs
Funding body | Department of Education, Training & Youth Affairs |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Research Infrastructure Block Grant (RIBG) |
Role | Lead |
Funding Start | 1995 |
Funding Finish | 1995 |
GNo | G0175577 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
Foam flows: Coupling between morphology and flow structures.$14,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Small Grant |
Role | Lead |
Funding Start | 1995 |
Funding Finish | 1995 |
GNo | G0174949 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
2nd Intern. Confer. on Gas Liquid Solid, UK, 27-29 March 1995$2,500
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Travel Grant |
Role | Lead |
Funding Start | 1995 |
Funding Finish | 1995 |
GNo | G0176827 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
19943 grants / $61,500
94 COLLAB.Differential sedimentation of non-flocculated particulate suspensions$43,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Laureate Professor Kevin Galvin, Emeritus Professor Graeme Jameson |
Scheme | Strategic Partnerships with Industry - Research & Training Scheme (SPIRT) |
Role | Investigator |
Funding Start | 1994 |
Funding Finish | 1994 |
GNo | G0173340 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Hydrocarbon solubility in partially-carbonated alkanolamine solutions and their blends.$16,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Small Grant |
Role | Lead |
Funding Start | 1994 |
Funding Finish | 1994 |
GNo | G0174834 |
Type Of Funding | Scheme excluded from IGS |
Category | EXCL |
UON | Y |
8th European Conference on Mixing (International event held once eery 3 years) - Cambridge - 21-23 Septemer 1994$2,500
Funding body: University of Newcastle
Funding body | University of Newcastle |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Travel Grant |
Role | Lead |
Funding Start | 1994 |
Funding Finish | 1994 |
GNo | G0175076 |
Type Of Funding | Internal |
Category | INTE |
UON | Y |
19931 grants / $604,400
93,94,95 COLLAB./AMIRA Ltd/ High Intensity Conditioning for Flotation$604,400
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson, Professor John Ralston |
Scheme | Strategic Partnerships with Industry - Research & Training Scheme (SPIRT) |
Role | Lead |
Funding Start | 1993 |
Funding Finish | 1995 |
GNo | G0173063 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
19922 grants / $503,000
Special Investigator Award$400,800
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Large Grant |
Role | Lead |
Funding Start | 1992 |
Funding Finish | 1994 |
GNo | G0173064 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Bubble-enhanced Sedimentation$102,200
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson, Assoc. Prof Ralph Weiland |
Scheme | Large Grant |
Role | Lead |
Funding Start | 1992 |
Funding Finish | 1994 |
GNo | G0173065 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
19911 grants / $85,000
Fluid Dynamics Of A New Device For Mineral Flotation$85,000
Funding body: ARC (Australian Research Council)
Funding body | ARC (Australian Research Council) |
---|---|
Project Team | Emeritus Professor Graeme Jameson |
Scheme | Large Grant |
Role | Lead |
Funding Start | 1991 |
Funding Finish | 1991 |
GNo | G0173834 |
Type Of Funding | Aust Competitive - Commonwealth |
Category | 1CS |
UON | Y |
Research Supervision
Number of supervisions
Current Supervision
Commenced | Level of Study | Research Title | Program | Supervisor Type |
---|---|---|---|---|
2022 | PhD | Studies in Fluidised Bed Flotation | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2006 | Honours | Behaviour and composition of a particle cloud in a continuously stirred vessel | Chemical Engineering, University of Newcastle | Sole Supervisor |
2006 | Honours | Instabilities in uniformly fluidised froths | Chemical Engineering, University of Newcastle | Sole Supervisor |
Past Supervision
Year | Level of Study | Research Title | Program | Supervisor Type |
---|---|---|---|---|
2016 | PhD | Fluidized Bed Flotation of Coarse Particles | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2016 | PhD | Influence of Turbulence on Bubble-particle Detachment in Floatation | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2016 | PhD | Influence of Turbulence on Bubble-particle Detachment in Floatation | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2015 | Masters | Oxygen Mass Transfer in Solid-Laden Liquids | M Philosophy (Chemical Eng), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2015 | PhD | Stabilisation of Bubbles and Froths with Colloidal Particles and Inorganic Electrolytes | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2014 | PhD | Behaviour of Bubble Clusters in a Turbulent Flotation Cell | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2014 | PhD | Studies of Froth Recovery in Flotation | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2013 | PhD | Process Engineering Fundamentals of Microalgae Production | PhD (Biological Sciences), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2013 | PhD | Detachment of Particles From Bubbles in a Turbulent Motion | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2013 | PhD | The Attachment of Bubbles to Composite Particles | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2012 | PhD | Triboelectric Charging and Particle Separation | PhD (Chemistry), College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2010 | PhD | The Effect of Magnetic Conditioning on the Froth Flotation of Ultrafine Metal Sulphides | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Sole Supervisor |
2009 | PhD | The Influence of Nanoparticle and Surfactant Interactions on Foam Stability | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2009 | PhD | Aggregate/Sediment Bed Property Relationships | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2006 | Honours | The just suspended speed for solids in a stirred vessel | Chemical Engineering, University of Newcastle | Sole Supervisor |
2006 | Honours | Liquid hold-up in flotation froths | Chemical Engineering, University of Newcastle | Sole Supervisor |
2006 | Honours | Effect of turbulence on the flotation of fine particles and nanoparticles | Chemical Engineering, University of Newcastle | Sole Supervisor |
2006 | PhD | A Kinetic Study of Aggregation: Quantification & Implications of Particle Collision Efficiency | PhD (Chemistry), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2006 | PhD | Aggregate Structure and Strength in Heteroaggregation | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2006 | Honours | Effect of contact angle on the strength of iron ore agglomerates | Chemical Engineering, University of Newcastle | Sole Supervisor |
2006 | Masters | The Recovery of Nanoparticles by Flotation | M Engineering (Chemical) [R], College of Engineering, Science and Environment, The University of Newcastle | Sole Supervisor |
2006 | Honours | Vortices in fluidised beds | Chemical Engineering, University of Newcastle | Sole Supervisor |
2006 | Honours | Experimental verification of a theory of water bell behaviour | Chemical Engineering, University of Newcastle | Sole Supervisor |
2005 | Masters | Rheology and Electrokinetics of Alumina Nanoparticle Suspensions: Effect of Particle Size, Volume Fraction and Monovalent Cations | M Engineering (Chemical) [R], College of Engineering, Science and Environment, The University of Newcastle | Co-Supervisor |
2005 | Honours | Bubble mineralisation in flotation | Chemical Engineering, University of Newcastle | Sole Supervisor |
2005 | Masters | A Study of Air-Filled Toroidal Vortex Rings | M Engineering (Chemical) [R], College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2005 | Honours | Liquid jet dispersion in rising froth | Chemical Engineering, University of Newcastle | Sole Supervisor |
2005 | Honours | Stimulus sensitive flocculation | Chemical Engineering, University of Newcastle | Sole Supervisor |
2005 | Honours | The froth phase flotation of particles | Chemical Engineering, University of Newcastle | Sole Supervisor |
2005 | Honours | Cluster formation and kinetic factors in flotation | Chemical Engineering, University of Newcastle | Sole Supervisor |
2005 | Honours | Capture of nanoparticles in flotation froths | Chemical Engineering, University of Newcastle | Sole Supervisor |
2005 | Honours | Capture of particles in the froth phase | Chemical Engineering, University of Newcastle | Sole Supervisor |
2004 | Honours | Transient froth stability and water recovery in flotation | Chemical Engineering, University of Newcastle | Sole Supervisor |
2004 | Honours | Effect of particle concentration on coagulation of latex particles | Chemical Engineering, University of Newcastle | Co-Supervisor |
2004 | Honours | Effect of electrolytes on zeta potential of coal suspensions | Chemical Engineering, University of Newcastle | Co-Supervisor |
2004 | Honours | Influence of salts on flotation kinetics of coal | Chemical Engineering, University of Newcastle | Co-Supervisor |
2004 | Honours | Flotation of oxidised coal | Chemical Engineering, University of Newcastle | Co-Supervisor |
2004 | Honours | Interfacial properties in flotation | Chemical Engineering, University of Newcastle | Co-Supervisor |
2004 | Honours | The flow from pins in a radially expanding film | Chemical Engineering, University of Newcastle | Co-Supervisor |
2004 | Honours | Movement of particles in a flotation froth | Chemical Engineering, University of Newcastle | Sole Supervisor |
2004 | PhD | Novel Routes for Polymer-Assisted Solid-Liquid Separation | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Sole Supervisor |
2004 | PhD | Gas Absorption in Foam Reactors | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Sole Supervisor |
2004 | Honours | The formation of bubble clusters in flotation | Chemical Engineering, University of Newcastle | Sole Supervisor |
2004 | Honours | The critical suspension speed in stirred tanks | Chemical Engineering, University of Newcastle | Sole Supervisor |
2004 | Honours | The charge at the oil/water interface | Chemical Engineering, University of Newcastle | Sole Supervisor |
2004 | Honours | Depletion flocculation of silica using silica nanoparticles | Chemical Engineering, University of Newcastle | Sole Supervisor |
2003 | Honours | The effect of surfactant concentration on bubble-particle attachment | Chemical Engineering, University of Newcastle | Sole Supervisor |
2003 | Honours | Behaviour of an impinging fountain jet | Chemical Engineering, University of Newcastle | Sole Supervisor |
2003 | Honours | Temperature sensitive flocculation and consolidation with biopolymers | Chemical Engineering, University of Newcastle | Co-Supervisor |
2003 | Honours | Moisture reduction in fine coal using dual polymer flocculation | Chemical Engineering, University of Newcastle | Co-Supervisor |
2002 | Honours | Factors influencing the stability of froths | Chemical Engineering, University of Newcastle | Sole Supervisor |
2002 | Honours | Flotation of coal in electrolyte solutions | Chemical Engineering, University of Newcastle | Co-Supervisor |
2002 | Honours | Zeta potentials of coal particles | Accounting, University of Newcastle | Co-Supervisor |
2002 | Honours | Optimum distribution of wash water in flotation | Chemical Engineering, University of Newcastle | Sole Supervisor |
2002 | Honours | Role of ion hydration on ion adsorption to hydrophobic surfaces | Chemical Engineering, University of Newcastle | Co-Supervisor |
2002 | Honours | Recovery of valuable minerals | Chemical Engineering, University of Newcastle | Sole Supervisor |
2002 | PhD | Intensification of Biological Fixed-film Processes Using a Fluidised-bed Bioreactor: Mass Transfer and Process Perspectives | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2002 | PhD | Froth Phenomena in Flotation | PhD (Chemical Engineering), College of Engineering, Science and Environment, The University of Newcastle | Principal Supervisor |
2002 | Honours | Using bipolymers in flocculation and stabilisation of suspensions | Chemical Engineering, University of Newcastle | Co-Supervisor |
2002 | Honours | The flow of liquid in a rising froth | Chemical Engineering, University of Newcastle | Sole Supervisor |
2002 | Honours | Measurement of bubble sizes in flotation cells | Chemical Engineering, University of Newcastle | Sole Supervisor |
2002 | Honours | Bubble clusters in flotation cells | Chemical Engineering, University of Newcastle | Co-Supervisor |
2001 | Honours | The liquid dispersion in drainage froths | Chemical Engineering, University of Newcastle | Sole Supervisor |
2001 | Honours | Froth drainage and liquid distribution in an industrial flotation plant | Chemical Engineering, University of Newcastle | Sole Supervisor |
2001 | Honours | A standard method for determining the contact angle of coal particles | Chemical Engineering, University of Newcastle | Co-Supervisor |
2001 | Honours | Measurement of dynamic surface tension of surfactants | Chemical Engineering, University of Newcastle | Sole 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 | 173 | |
United Kingdom | 41 | |
India | 5 | |
Sweden | 4 | |
Bulgaria | 3 | |
More... |
News
News • 22 Nov 2019
OPINION: Newcastle know-how to our region and the world
If I told you Australia’s biggest-earning innovation for the past quarter century came from Newcastle, would you believe me? Indeed, it has outstripped earnings from other icons like WiFi and the Black Box, but is little known for its economic contribution to the country.
News • 15 Aug 2019
Laureate Professor receives global gong for outstanding research
A novel flotation device developed by the University of Newcastle’s Laureate Professor Graeme Jameson AO has taken out this year’s CEEC Medal for Technical Research.
News • 25 Feb 2019
New technology offers promising manufacturing potential for Australia
An innovative low emission technology could see the development of a new manufacturing industry within Australia.
News • 10 May 2018
Laureate Professor Graeme Jameson joins global list of most outstanding scientists
University of Newcastle chemical engineer Laureate Professor Graeme Jameson AO has been honoured by one of the most prestigious organisations in the world – the Royal Society, which boasts a fellowship of 1,600 of the world’s most eminent scientists.
News • 10 Oct 2016
Laureate professor honoured for lifetime achievement
University of Newcastle Laureate Professor Graeme Jameson AO has been honoured as the recipient of the Lifetime Achievement Award at the International Mineral Processing Congress (IMPC), held in Quebec City, Canada.
News • 21 Oct 2015
UON Researcher Awarded Australia’s Top Innovator
University of Newcastle Laureate Professor Graeme Jameson AO, has become the inaugural recipient of the Prime Minister's Prize for Innovation.
News • 11 May 2015
Jameson Cell - $36 billion value to the economy
Laureate Professor Graeme Jameson's invention, the Jameson Cell, has been estimated as adding $36 billion to the Australian economy from 1990 to the end of 2014, according to a recent independent report from Manford Pty Ltd.
News • 10 Feb 2015
Laureate Professor elected to esteemed American academy
Laureate Professor Graeme Jameson, Professor of Chemical Engineering and Director of the Centre for Multiphase Processes has been elected to the US National Academy of Engineering (NAE).
News • 1 Nov 2013
NSW Scientist of the Year
University of Newcastle Laureate Professor Graeme Jameson AO has been awarded the NSW Scientist of the Year at the 2013 NSW Science and Engineering Awards held tonight at Government House in Sydney.
News • 21 Feb 2013
Newcastle trailblazer wins prestigious global award
Laureate Professor Graeme Jameson AO, the inventor of the acclaimed Jameson Cell, has won another prestigious global award to add to his already impressive list of awards and medals gathered during an illustrious career as a scientist and researcher.
Emeritus Professor Graeme Jameson
Position
Emeritus Professor
School of Engineering
College of Engineering, Science and Environment
Focus area
Chemical Engineering
Contact Details
graeme.jameson@newcastle.edu.au | |
Phone | (02) 4921 6181 |
Fax | (02) 4960 1445 |
Office
Room | EB111 |
---|---|
Building | Engineering B - Chemical |
Location | Callaghan University Drive Callaghan, NSW 2308 Australia |