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.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882357
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
A Computational Facility for Multi-scale Modelling in Bio and Nanotechnology. Bio- and nanotechnology have the potential to transform Australian industry and research, and to bring significant benefits for consumers. The scope will include materials for energy storage, medical diagnostics and cellular imaging, bioengineering, drug and gene delivery, improved foods by molecular design, novel materials for electronics, improved techniques for particle processing, and molecular sieves for filtering ....A Computational Facility for Multi-scale Modelling in Bio and Nanotechnology. Bio- and nanotechnology have the potential to transform Australian industry and research, and to bring significant benefits for consumers. The scope will include materials for energy storage, medical diagnostics and cellular imaging, bioengineering, drug and gene delivery, improved foods by molecular design, novel materials for electronics, improved techniques for particle processing, and molecular sieves for filtering/purifying water and gases. The dedicated computing facility will enable a fast interactive cycle between simulation and experiment in these areas, accelerating the pace of research and applications.Read moreRead less
Energy Conversion and Signal Transduction in Nanomechanical Systems. Miniaturization of materials and electronic devices is an important technological goal. In order to make smaller working devices,we need to understand how to create molecular scale devices such as valves, switches, pumps and motors. This Fellowship will explore ways to make smaller, portable devices that can be used for personal health monitoring,environmental sensing and the detection of disease and pathogens.
Disorder and Dynamics in Superionic Conductors. This project will pursue a powerful new approach to superionic conductors, an important class of advanced materials that are critical to the development of clean-energy technologies, such as solid-oxide fuel cells. This will be a new direction for Australian science in the theoretical treatment of material properties. The project will also make significant progress in the computer-aided design of advanced materials, and in the simulation methods th ....Disorder and Dynamics in Superionic Conductors. This project will pursue a powerful new approach to superionic conductors, an important class of advanced materials that are critical to the development of clean-energy technologies, such as solid-oxide fuel cells. This will be a new direction for Australian science in the theoretical treatment of material properties. The project will also make significant progress in the computer-aided design of advanced materials, and in the simulation methods themselves, contributing to pure science in the form of our understanding of the physics and chemistry of materials at the most fundamental level. Read moreRead less
The First Chemically Accurate Tools in Theoretical Materials Research. Non-metallic materials are widely used in catalytic, separation and sensing applications. This project will create a new, accurate, general and systematic approach to the computational study of non-metallic materials and will provide an enormous step forward in our ability to design these materials for specific applications. With ever increasing demand, growing world population and shrinking natural resources, the benefits of ....The First Chemically Accurate Tools in Theoretical Materials Research. Non-metallic materials are widely used in catalytic, separation and sensing applications. This project will create a new, accurate, general and systematic approach to the computational study of non-metallic materials and will provide an enormous step forward in our ability to design these materials for specific applications. With ever increasing demand, growing world population and shrinking natural resources, the benefits of such rational materials design impact on the development of new, safer, more efficient, reusable materials in chemical, engineering, electronic and biological applications. Read moreRead less
Special Research Initiatives - Grant ID: SR0354636
Funder
Australian Research Council
Funding Amount
$30,000.00
Summary
Australian Computational Molecular Science Network. Computational Molecular Science (CMS) involves the use of theory and computational methods to simulate and visualise molecular systems ranging from small atmospheric species to proteins, nucleic acids, chemical polymers and materials. It represents our most incisive expression of what we understand about the molecular basis of nature. The CMS network will integrate and cross-fertilize both fundamental and application-based expertize in molecula ....Australian Computational Molecular Science Network. Computational Molecular Science (CMS) involves the use of theory and computational methods to simulate and visualise molecular systems ranging from small atmospheric species to proteins, nucleic acids, chemical polymers and materials. It represents our most incisive expression of what we understand about the molecular basis of nature. The CMS network will integrate and cross-fertilize both fundamental and application-based expertize in molecular scale computations in the fields of nanoscience, biomaterials, biotechnology, biomedical science and environmental science. It will uncover and explore critical new interdisciplinary science and create new molecular-based paradigms that will drive advances in these fields over the next decade.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0237958
Funder
Australian Research Council
Funding Amount
$133,000.00
Summary
An enclosive flow Cooling cell for spectroscopic studies. We wish to install a low temperature absorption cell that will be coupled to high resolution spectrometer systems operating in the infrared, visible and ultra-violet regions of the spectrum. This will enable us to further develop techniques for the study of the structures, dynamics and kinetics of molecules of biological and atmospheric significance. This will lead to a better understanding of the structures, dynamics and reaction kinetic ....An enclosive flow Cooling cell for spectroscopic studies. We wish to install a low temperature absorption cell that will be coupled to high resolution spectrometer systems operating in the infrared, visible and ultra-violet regions of the spectrum. This will enable us to further develop techniques for the study of the structures, dynamics and kinetics of molecules of biological and atmospheric significance. This will lead to a better understanding of the structures, dynamics and reaction kinetics of these species and in the case of atmospheric species also provide molecular parameters required for atmospheric monitoring.Read moreRead less
Atomistic Mechanisms of Stress Relaxation in Amorphous Materials. Amorphous materials represent a major thrust in the search for new materials. Metallic glasses have very high strength and can be cast to much finer tolerances than regular (polycrystalline) metals. Ceramic glasses are finding increasing applications in data storage, photoelectronics and fibre optics. The greatest obstacle to the application of amorphous solids is their brittleness. The goal of this project is to use accurate comp ....Atomistic Mechanisms of Stress Relaxation in Amorphous Materials. Amorphous materials represent a major thrust in the search for new materials. Metallic glasses have very high strength and can be cast to much finer tolerances than regular (polycrystalline) metals. Ceramic glasses are finding increasing applications in data storage, photoelectronics and fibre optics. The greatest obstacle to the application of amorphous solids is their brittleness. The goal of this project is to use accurate computer simulations to provide detailed pictures of how atomic motions relax stress in very different types of glasses and, through this insight, explore ways of modifying the mechanical properties of these materials.Read moreRead less
Fluctuation Effects in Non-Crystallising Liquids. Understanding the behaviour of liquids colder than their freezing temperature is important in areas as diverse as metal alloy preparation, prevention of cell damage in plants and animals at low temperatures, extending the working temperature range of new high voltage automotive batteries and controlling drug delivery in pharmaceuticals. Advances in these areas would represent important new manufacturing opportunities in industries already establi ....Fluctuation Effects in Non-Crystallising Liquids. Understanding the behaviour of liquids colder than their freezing temperature is important in areas as diverse as metal alloy preparation, prevention of cell damage in plants and animals at low temperatures, extending the working temperature range of new high voltage automotive batteries and controlling drug delivery in pharmaceuticals. Advances in these areas would represent important new manufacturing opportunities in industries already established in Australia. In this project the fundamental physical chemistry of supercooled liquids is developed and applied to a number of these technological challenges.Read moreRead less
Optimum design of controlled drug delivery systems. Controlled drug delivery systems are ideal to achieve localised release of drugs at an effective rate for a prolonged period. They have the merit of optimising drug absorption by a body, relieving patients from frequent administration and high dosage of drugs which often result in drug wastage, patients' inconvenience and more importantly the side effects that can be fatal. The success of this project will (1) enhance the Australia pharmaceutic ....Optimum design of controlled drug delivery systems. Controlled drug delivery systems are ideal to achieve localised release of drugs at an effective rate for a prolonged period. They have the merit of optimising drug absorption by a body, relieving patients from frequent administration and high dosage of drugs which often result in drug wastage, patients' inconvenience and more importantly the side effects that can be fatal. The success of this project will (1) enhance the Australia pharmaceutical industry's competitiveness in the global market, (2) provide good medication for the treatment of various diseases, promoting good health of Australians, (3) lead to new mathematical models and solutions that are also applicable to such fields as resources and environmental systems.Read moreRead less