Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0221983
Funder
Australian Research Council
Funding Amount
$900,000.00
Summary
Interface, Particle and Complex Fluid Characterisation Laboratory. This laboratory will provide a state-of-the-art characterisation facility for complex fluids. This will service the needs of 27 research staff and 38 postgraduate students and involve collaboration between twelve major research groups based at the Universities of Melbourne, Newcastle, Monash, La Trobe and RMIT. The facility will enhance the research activities of the collaborating institutions in key strategic areas. The laborat ....Interface, Particle and Complex Fluid Characterisation Laboratory. This laboratory will provide a state-of-the-art characterisation facility for complex fluids. This will service the needs of 27 research staff and 38 postgraduate students and involve collaboration between twelve major research groups based at the Universities of Melbourne, Newcastle, Monash, La Trobe and RMIT. The facility will enhance the research activities of the collaborating institutions in key strategic areas. The laboratory will also act as a facility for undertaking consulting projects with industry groups by the applicants.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560758
Funder
Australian Research Council
Funding Amount
$187,000.00
Summary
Dynamics at Interfaces: a facility for the characterisation of the dynamics of structural reorganisation and adsorption at interfaces. Controlling the flow, stability, and general performance of finely dispersed materials is important in a great number of industries from cosmetics to minerals purification. These properties are often controlled by the addition of material that forms a film at the interface between the dispersed material and the solvent. We seek to develop a facility that will ena ....Dynamics at Interfaces: a facility for the characterisation of the dynamics of structural reorganisation and adsorption at interfaces. Controlling the flow, stability, and general performance of finely dispersed materials is important in a great number of industries from cosmetics to minerals purification. These properties are often controlled by the addition of material that forms a film at the interface between the dispersed material and the solvent. We seek to develop a facility that will enable the properties of this film to be characterized, in particular the rate at which the film responds to mechanical and chemical changes. With this knowledge we hope to relate the nanoscopic properties of the adsorbed film to macroscopic properties of the dispersion and be able to tune the structure of the surface film, in order to control the bulk properties of complex fluids.Read moreRead less
Pulsed oscillating mass analyser. Mass spectrometers are ubiquitous components in chemical analysis, but are often large and expensive. We have developed a new method for mass analysis, which is smaller and cheaper than existing technology. However, the analyser needs further research to determine whether it has the performance specifications to match the other technologies. The objective of this research is to characterise, explore and extend the prototype and to develop the appropriate math ....Pulsed oscillating mass analyser. Mass spectrometers are ubiquitous components in chemical analysis, but are often large and expensive. We have developed a new method for mass analysis, which is smaller and cheaper than existing technology. However, the analyser needs further research to determine whether it has the performance specifications to match the other technologies. The objective of this research is to characterise, explore and extend the prototype and to develop the appropriate mathematical algorithm for mass analysis. Success in this project may lead to a new mass analyser that can be incorporated into analytical instruments, many of which are manufactured in Australia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560672
Funder
Australian Research Council
Funding Amount
$202,705.00
Summary
Ultrafast laser facility for chemical, biological and physical investigations of advanced materials. Ultrafast laser techniques are becoming indispensable in many diverse scientific disciplines. Within the Australian scientific community, there is a great need for enhanced access to sophisticated ultrafast laser instrumentation. The expansion to the femtosecond laser facility through the addition of state-of-the-art laser devices, will enable novel laser spectroscopy measurements and advanced op ....Ultrafast laser facility for chemical, biological and physical investigations of advanced materials. Ultrafast laser techniques are becoming indispensable in many diverse scientific disciplines. Within the Australian scientific community, there is a great need for enhanced access to sophisticated ultrafast laser instrumentation. The expansion to the femtosecond laser facility through the addition of state-of-the-art laser devices, will enable novel laser spectroscopy measurements and advanced optical microscopy techniques to be applied to investigations of advanced materials and biological systems. Access to such instrumentation is crucial to fields including photoluminescent conductive polymers, nanoparticles, engineered supramolecules for artificial photosynthetic systems, and photoactivated therapy and drug delivery/release technology.Read moreRead less
The Interface of Oil-in-Water Emulsions. The interface between two immiscible liquids controls many phenomena including the formation and properties of emulsions, the nature of many chemical separation processes and the behaviour of biological systems. There are few methods to study such interfaces and most of these are susceptible to trace contamination by adventitious surfactants, but emulsions with their large surface area avoid this problem. Significant advances are possible with the new Aus ....The Interface of Oil-in-Water Emulsions. The interface between two immiscible liquids controls many phenomena including the formation and properties of emulsions, the nature of many chemical separation processes and the behaviour of biological systems. There are few methods to study such interfaces and most of these are susceptible to trace contamination by adventitious surfactants, but emulsions with their large surface area avoid this problem. Significant advances are possible with the new Australian technique of electroacoustics, complemented by neutron scattering, nmr, rheological and dielectric response measurements on concentrated emulsions. Our surfactant-free emulsions provide a fundamental breakthrough in such studies, leading to new materials from nanostructures.Read moreRead less
Poly-crystalline Thin Films for LASER Applications. This project is based on a recent discovery which reports LASER emission in disordered media such as polycrystalline ZnO. This behaviour appears to be related to the crystallographic properties of ZnO (wurztite) material. Using a novel deposition process the defect density, size of crystallites and macroscopic orientation within such thin films will be controlled independently. This will provide an opportunity to study the fundamental basis of ....Poly-crystalline Thin Films for LASER Applications. This project is based on a recent discovery which reports LASER emission in disordered media such as polycrystalline ZnO. This behaviour appears to be related to the crystallographic properties of ZnO (wurztite) material. Using a novel deposition process the defect density, size of crystallites and macroscopic orientation within such thin films will be controlled independently. This will provide an opportunity to study the fundamental basis of such behaviour. In conjunction with this the development of structure in similarly produced GaN (wurztite) films will be examined. This work should also provide practical information concerning the potential performance of LASER devices based on disordered materials.Read moreRead less
Nanostructured Carbon Electrodes. The development of higher capacity energy storage devices is critical to the efficient use of energy. The fundamental knowledge gained in this project will enable the production of the next generation advanced electrode materials for this purpose and hence provide many new commercial opportunities for Australian industry. The project brings together world leaders in their own fields to address a highly multidisciplinary area of research and will provide an excel ....Nanostructured Carbon Electrodes. The development of higher capacity energy storage devices is critical to the efficient use of energy. The fundamental knowledge gained in this project will enable the production of the next generation advanced electrode materials for this purpose and hence provide many new commercial opportunities for Australian industry. The project brings together world leaders in their own fields to address a highly multidisciplinary area of research and will provide an excellent training for PhD students and post doctoral Research Fellows, enabling them to work in and contribute to the development of new nanotechnology industries in Australia.Read moreRead less
Closing the Future: New Foundations for the Physics of Possibility. The distinction between a fixed and an open future is deeply embedded in human thought, and also central to some of the most profound puzzles in contemporary physics. By revealing the human origins of out fundamental concepts of possibility in time, this project will enhance our understanding of one of the most basic features of our experience of the world, lay foundations for a new treatment of time and possibility in foundame ....Closing the Future: New Foundations for the Physics of Possibility. The distinction between a fixed and an open future is deeply embedded in human thought, and also central to some of the most profound puzzles in contemporary physics. By revealing the human origins of out fundamental concepts of possibility in time, this project will enhance our understanding of one of the most basic features of our experience of the world, lay foundations for a new treatment of time and possibility in foundamental physics, and throw important new light on the mysteries of the quantum world.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883030
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
High-Resolution Field Emission Scanning Electron Microscopy (FESEM) Platform for Characterisation at the Nanometre-Level. The Field Emission Scanning Electron Microscope (FESEM) is designed to provide fundamental insights into physical and biological systems though characterisation and analysis of structures on nanometre length scales. This versatile instrument will support a wide range of research projects covering all four national research priorities. These range from the characterisation of ....High-Resolution Field Emission Scanning Electron Microscopy (FESEM) Platform for Characterisation at the Nanometre-Level. The Field Emission Scanning Electron Microscope (FESEM) is designed to provide fundamental insights into physical and biological systems though characterisation and analysis of structures on nanometre length scales. This versatile instrument will support a wide range of research projects covering all four national research priorities. These range from the characterisation of light alloys to boost and intensify Australia's aluminium, magnesium and titanium alloy industries, to tissue engineering for the repair of human elastic tissues in skin, artery, bladder and lung, to the study of microtubules in plant cells for genetic manipulation of plants to withstand environmental stresses such as drought or salinity.Read moreRead less
Novel 3D Carbon Architectures for Fuel Cell Applications. The implementation of clean energy technologies has clear economic, environmental and social benefits for Australia, its industries and population. This project has the potential to make a significant impact on fuel cell research as an alternative means of energy production. We aim to remove some of the technical and economic barriers through product and process innovation at the nanoscale. Building on a strong track record in advanced ma ....Novel 3D Carbon Architectures for Fuel Cell Applications. The implementation of clean energy technologies has clear economic, environmental and social benefits for Australia, its industries and population. This project has the potential to make a significant impact on fuel cell research as an alternative means of energy production. We aim to remove some of the technical and economic barriers through product and process innovation at the nanoscale. Building on a strong track record in advanced materials research, this project investigates the integration of novel carbon nanostructures with extraordinary properties to produce high performance electrodes, that should lead to significant improvement in fuel cell performance.Read moreRead less