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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
Analysis, Optimization, and Control of Scanning Atomic Force Microscope Micro-Cantilever Probes. Atomic Force Microscopes (AFM's) are widely used for the examination of samples smaller than can be observed with an optical microscope. A tiny 'finger', only a few atoms wide at its sharpest point, is used to 'feel' the surface of a sample. This project aims to increase the resolution of AFM images by actively controlling the sensor probe dynamics.
Better quality AFM images would allow scientists ....Analysis, Optimization, and Control of Scanning Atomic Force Microscope Micro-Cantilever Probes. Atomic Force Microscopes (AFM's) are widely used for the examination of samples smaller than can be observed with an optical microscope. A tiny 'finger', only a few atoms wide at its sharpest point, is used to 'feel' the surface of a sample. This project aims to increase the resolution of AFM images by actively controlling the sensor probe dynamics.
Better quality AFM images would allow scientists to further investigate the atomic and molecular structure of such samples as: metals, polymers, cells, and proteins.
This research will contribute to the design of an Australian made Scanning Probe Microscope. Development of local expertise will provide a valuable resource for Australian scientific and industrial research.
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Novel 2-photon atom manipulation for ultra-nanoscale processing of diamond. There is intense interest in exploiting diamond's remarkable properties in many fields of science and technology, but fabricating and processing devices remains a major challenge. This project will build on previous work, using a recently discovered novel laser-induced surface phenomenon that enables, for the first time for any material, the exciting prospect of using light to manipulate surface atoms with atomic precis ....Novel 2-photon atom manipulation for ultra-nanoscale processing of diamond. There is intense interest in exploiting diamond's remarkable properties in many fields of science and technology, but fabricating and processing devices remains a major challenge. This project will build on previous work, using a recently discovered novel laser-induced surface phenomenon that enables, for the first time for any material, the exciting prospect of using light to manipulate surface atoms with atomic precision. This project aims to elucidate the mechanisms underpinning the optical interaction to reveal its full potential and use it to address key problems in diamond nano-device fabrication that lie beyond the reach of current techniques. It is expected that the outcomes will directly enhance Australia's current strengths in diamond-based quantum and photonic technologies.Read moreRead less
Nanotribology of coating on silicon using multiscale atomic-continuum modelling. Nanotribology plays a vital role in the development of nanomaterials, nanotechnology and information technology. The current project aims to predict the mechanisms involved in the nanotribology of diamond coating on silicon. In addition, the project will integrate the tribological mechanisms involved on the atomic scale with mechanisms on the continuum scale using an innovative model combining molecular dynamics, ....Nanotribology of coating on silicon using multiscale atomic-continuum modelling. Nanotribology plays a vital role in the development of nanomaterials, nanotechnology and information technology. The current project aims to predict the mechanisms involved in the nanotribology of diamond coating on silicon. In addition, the project will integrate the tribological mechanisms involved on the atomic scale with mechanisms on the continuum scale using an innovative model combining molecular dynamics, discrete elements method and finite elements analysis. This will provide a holistic understanding of tribology.Read moreRead less
Rational Design of Novel Multiferroic Materials for Energy Harvesting and Energy Efficiency. Multiferroics are a class of fundamentally complex materials in which several ferroic orders (for example, ferroelectric and ferromagnetic) coexist. The coupling between their electric and magnetic degrees of freedom is controllable via stress and external fields, thus opening the possibility for breakthrough technological developments. By working at the frontier of complex nanostructured oxide materials ....Rational Design of Novel Multiferroic Materials for Energy Harvesting and Energy Efficiency. Multiferroics are a class of fundamentally complex materials in which several ferroic orders (for example, ferroelectric and ferromagnetic) coexist. The coupling between their electric and magnetic degrees of freedom is controllable via stress and external fields, thus opening the possibility for breakthrough technological developments. By working at the frontier of complex nanostructured oxide materials, this project aims to establish the rational basis for systematic design of novel artificially layered multiferroics, develop accurate and computationally affordable methods to simulate these materials under finite-temperature conditions, and exploit this knowledge to devise likely revolutionary photovoltaic, nanoelectronic and energy conversion applications.Read moreRead less
Characterisation and Modelling of Nanostructured Soft Magnetic Materials for Advanced Electromagnetic Applications. This project bridges the gap between nanomagnetic materials and practical applications. The knowledge generated and the international collaborations with world class scientists established through this cutting-edge research project will strengthen the leading status of Australia in the field of nanoscience and nanotechnology. The research outcomes will stimulate the growth of world ....Characterisation and Modelling of Nanostructured Soft Magnetic Materials for Advanced Electromagnetic Applications. This project bridges the gap between nanomagnetic materials and practical applications. The knowledge generated and the international collaborations with world class scientists established through this cutting-edge research project will strengthen the leading status of Australia in the field of nanoscience and nanotechnology. The research outcomes will stimulate the growth of world class Australian industries and hence the national economy through the commercial manufacturing of hi-tech nanomagnetic materials and innovative smart devices and systems. High quality PhD and honours project students will be trained.Read moreRead less
Self-organised complex ionised gas systems for ordered nanometre-scale assemblies. This proposal is to develop the physical principles of nano-scale assembly processes in complex plasmas. Novel approaches for tailoring the plasma-grown building blocks and controllable deposition of ordered nanoparticle arrays on nanopatterned solids are targeted. The fundamentals of the multi-scale dynamic processes will be elucidated and existing techniques for developing new materials and electronic/photonic d ....Self-organised complex ionised gas systems for ordered nanometre-scale assemblies. This proposal is to develop the physical principles of nano-scale assembly processes in complex plasmas. Novel approaches for tailoring the plasma-grown building blocks and controllable deposition of ordered nanoparticle arrays on nanopatterned solids are targeted. The fundamentals of the multi-scale dynamic processes will be elucidated and existing techniques for developing new materials and electronic/photonic devices will be advanced. The expected outcomes are highly relevant for the nano-materials and optoelectronic technologies, rapidly emerging areas of high-tech industries worldwide.Read moreRead less
CNTs-modified polymer composites for tribological applications. The growth of the Australian economy relies on continuous improvements in all sectors of production, manufacturing, operation and management where tribology is playing a significant role. System failure relevant to wear and friction over years and its impact on the Australian economy have continued to be a challenge for the community in the new century. The project is at the forefront of materials research, and the outcomes will pro ....CNTs-modified polymer composites for tribological applications. The growth of the Australian economy relies on continuous improvements in all sectors of production, manufacturing, operation and management where tribology is playing a significant role. System failure relevant to wear and friction over years and its impact on the Australian economy have continued to be a challenge for the community in the new century. The project is at the forefront of materials research, and the outcomes will provide (1) novel technical ways to optimise tribological performance of industrial contacting components, and (2) development of new wear resistant materials. The project will give Australia a competitive edge in the advances of tribology and nanotechnologyRead moreRead less
Complex plasmas: self-organized dusty matter from nanotechnology to astrophysics. The importance of complex plasmas is based on their intricate self-organized behaviour, on their rich variety in nature and extensive use in the laboratory and advanced technologies. This project aims at breakthrough results advancing the fundamental knowledge and contributing to frontier technologies such as nanoelectronics and nanotechnology as well as reliability of space technological systems and communication ....Complex plasmas: self-organized dusty matter from nanotechnology to astrophysics. The importance of complex plasmas is based on their intricate self-organized behaviour, on their rich variety in nature and extensive use in the laboratory and advanced technologies. This project aims at breakthrough results advancing the fundamental knowledge and contributing to frontier technologies such as nanoelectronics and nanotechnology as well as reliability of space technological systems and communications. The project will boost fundamental and applied aspects of the Australian science as well as international collaborative links of Australian research and technology by allowing access and involvement to advanced multi-national programs and high-profile experiments such as those on board the International Space Station.Read moreRead less