Optimising Froth Zone Performance in Mineral Flotation. Froth flotation is the most widely applied technique for the selective separation of valuable mineral from gangue mineral particles. This project aims to optimize the selective separation of valuable minerals from gangue minerals within the froth zone of flotation. This project has very high national significance as deficiencies in the froth zone performance of industrial flotation plants, leads to a significant loss of valuable mineral f ....Optimising Froth Zone Performance in Mineral Flotation. Froth flotation is the most widely applied technique for the selective separation of valuable mineral from gangue mineral particles. This project aims to optimize the selective separation of valuable minerals from gangue minerals within the froth zone of flotation. This project has very high national significance as deficiencies in the froth zone performance of industrial flotation plants, leads to a significant loss of valuable mineral from mineral concentrates, as well as a reduction in concentrate grade and quality. An expected outcome of this project will be a series of new tools and methodologies to optimize froth zone performance, which will have industry wide application.Read moreRead less
Optimizing tailings dewatering through interfacial chemistry and particle interactions. This project aims to improve the dewatering behaviour of waste tailings from mineral processing activites. Dewatering and disposal of tailings containing fine particles are serious issues which confront the mineral industry. Effective dewatering of tailings is determined by particle-solution interfacial chemistry and particle interactions. These properties will be manipulated by matching the molecular arch ....Optimizing tailings dewatering through interfacial chemistry and particle interactions. This project aims to improve the dewatering behaviour of waste tailings from mineral processing activites. Dewatering and disposal of tailings containing fine particles are serious issues which confront the mineral industry. Effective dewatering of tailings is determined by particle-solution interfacial chemistry and particle interactions. These properties will be manipulated by matching the molecular architecture and functionality of flocculants to mineral particle surface chemistry. Optimization of tails interfacial chemistry and particle interactions through conventional and non-conventional flocculants will be investigated and electoosmosis will be applied to achieve maximum dewatering behaviour.The scientific and environmental outcomes will be beneficial to all stakeholders.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0345760
Funder
Australian Research Council
Funding Amount
$210,000.00
Summary
Nanoscale Interaction Forces in Particulate and Molecular Systems. We seek to establish a world-class facility for the measurement of nanoscale interaction forces. The ability to measure forces between particles, polymers, emulsion droplets, bubbles, proteins and powders will augment our research capabilities in minerals and material processing, thin film technology, structured surfaces, and in molecular and bio-technology (eg. proteins, DNA, cells, bone, bio-implants). A Molecular Force Probe ....Nanoscale Interaction Forces in Particulate and Molecular Systems. We seek to establish a world-class facility for the measurement of nanoscale interaction forces. The ability to measure forces between particles, polymers, emulsion droplets, bubbles, proteins and powders will augment our research capabilities in minerals and material processing, thin film technology, structured surfaces, and in molecular and bio-technology (eg. proteins, DNA, cells, bone, bio-implants). A Molecular Force Probe (Asylum Research) instrument will allow precise and flexible force measurements on the nano-metre scale. The proposed multi-disciplinary facility will advance research in the areas of engineering, chemistry, pharmacology and biotechnology.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560679
Funder
Australian Research Council
Funding Amount
$932,870.00
Summary
Materials and Surface Characterisation Facility. Australian scientists are well positioned to be at the forefront of nanotechnology, biotechnology and advanced materials development. The proposed Facility, housing state-of-the-art equipment, will enable cutting-edge research in these areas by internationally renowned researchers at the University of Melbourne, Monash University, RMIT University, and CSIRO. Such research will facilitate the development of advanced materials for diverse applicatio ....Materials and Surface Characterisation Facility. Australian scientists are well positioned to be at the forefront of nanotechnology, biotechnology and advanced materials development. The proposed Facility, housing state-of-the-art equipment, will enable cutting-edge research in these areas by internationally renowned researchers at the University of Melbourne, Monash University, RMIT University, and CSIRO. Such research will facilitate the development of advanced materials for diverse applications including drug delivery, quantum computing, photonics and tissue engineering. The multi-user Facility will enable closer collaboration with researchers in academia and industry, and will be integral in training the next generation of Australian scientists in the nano- and biosciences.Read moreRead less
Controlled Macromolecular Architectures for Functional Nanomaterials Design. The research involves an exciting and innovative collaboration between two internationally recognized Australian research groups, cementing Australia's position as a leading country for research in polymer science and nanotechnology. Advanced polymer chemistry will be used to make ?smart? polymers that can controllably respond to changes in their surroundings. These will then be assembled to form materials with dimensio ....Controlled Macromolecular Architectures for Functional Nanomaterials Design. The research involves an exciting and innovative collaboration between two internationally recognized Australian research groups, cementing Australia's position as a leading country for research in polymer science and nanotechnology. Advanced polymer chemistry will be used to make ?smart? polymers that can controllably respond to changes in their surroundings. These will then be assembled to form materials with dimensions of the order of millionths of millimeters - forming so-called "smart nanomaterials". The materials prepared are expected to find application in the agricultural and pharmaceutical sectors, contributing to the well-being of Australian citizens and the development of a robust Australian industry.Read moreRead less
Nanotribology-The Chemical Rolling Resistance of Single Nanocrystals. Australian efforts in biosensors, environmental monitoring and mobile-health are predicated on the establishment of a nanotechnology based manufacturing sector. The key to this will be understanding how ultrasmall mechanical devices work. This application explores how we can make novel mechanical devices from molecules and small crystals.
Biodegradable polymeric microparticles for targeted delivery. The use of microparticles with tuneable physicochemical properties and loading characteristics is of interest in the fields of biomaterials, drug delivery and imaging. Such engineered particles are likely to address problems associated with conventional drugs and drug carriers, including poor disease site selectivity, polymer toxicity, non-biodegradability and free diffusion of drugs throughout the body. These microparticles may provi ....Biodegradable polymeric microparticles for targeted delivery. The use of microparticles with tuneable physicochemical properties and loading characteristics is of interest in the fields of biomaterials, drug delivery and imaging. Such engineered particles are likely to address problems associated with conventional drugs and drug carriers, including poor disease site selectivity, polymer toxicity, non-biodegradability and free diffusion of drugs throughout the body. These microparticles may provide direct advantages to society, including minimally invasive and fast in-vivo diagnostics, localised delivery of drugs and therapeutic agents with increased bioavailability, patient acceptability and reduced healthcare costs.Read moreRead less
Advanced nanoparticle stabilisation and functionalisation: small particles with huge potential. Australia is strongly investing in nanotechnology and through the governments priority goals 'Frontier Technologies for Building and Transforming Australian Industries' it has been recognised as an important area for investment. This proposal will help develop an internationally recognised nano-industry. It is envisaged that the particles made during this work will have direct implications for the pub ....Advanced nanoparticle stabilisation and functionalisation: small particles with huge potential. Australia is strongly investing in nanotechnology and through the governments priority goals 'Frontier Technologies for Building and Transforming Australian Industries' it has been recognised as an important area for investment. This proposal will help develop an internationally recognised nano-industry. It is envisaged that the particles made during this work will have direct implications for the public - creating a new class of medical diagnostic particles with better resolution and specificity. These particles have the potential to diagnose patients more precisely and at an earlier stage than is currently available. Additionally, these particles could be designed to load drugs and hence could be used to treat diseases such as cancer.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668382
Funder
Australian Research Council
Funding Amount
$1,000,000.00
Summary
e-Research Infrastructure for the Molecular and Materials Structure Sciences. Understanding molecular and materials structure in atomic detail is vital to a knowledge-based economy and a healthy society. The development of smart materials, nanotechnological devices, hydrogen storage materials, molecular switches, magnets and sensors, for example, depends on knowledge of three-dimensional atomic structure. Cures for illnesses such as SARS, AIDS and Alzheimer's disease and understanding the aging ....e-Research Infrastructure for the Molecular and Materials Structure Sciences. Understanding molecular and materials structure in atomic detail is vital to a knowledge-based economy and a healthy society. The development of smart materials, nanotechnological devices, hydrogen storage materials, molecular switches, magnets and sensors, for example, depends on knowledge of three-dimensional atomic structure. Cures for illnesses such as SARS, AIDS and Alzheimer's disease and understanding the aging process depends on knowledge of biomolecular structure. The deployment and development of automation-enhanced remote access to structural instruments through the web will greatly enhance Australian structure-based research, and make this science accessible to the public. Read moreRead less
DEVELOPMENT OF A NOVEL BIOMATERIAL FOR BONE TISSUE ENGINEERING. Tissue engineering of bone is emerging as a viable therapy for treating large defects in load-bearing bone. We wish to develop methods for combining novel heparan sulphate molecules (known to deliver growth factors to cell surfaces and thereby cause changes in bone cell phenotype) with load-bearing, macro-porous, biodegradable mineral/polymer biomaterials. Through the study of release profiles, protein adsorption and cell responses ....DEVELOPMENT OF A NOVEL BIOMATERIAL FOR BONE TISSUE ENGINEERING. Tissue engineering of bone is emerging as a viable therapy for treating large defects in load-bearing bone. We wish to develop methods for combining novel heparan sulphate molecules (known to deliver growth factors to cell surfaces and thereby cause changes in bone cell phenotype) with load-bearing, macro-porous, biodegradable mineral/polymer biomaterials. Through the study of release profiles, protein adsorption and cell responses to these derivatised biomaterials, a novel approach to bone replacement materials can be developed.Read moreRead less