Controlled manipulation of matter-waves in atomic waveguiding structures. This project will enable Australian researchers to actively participate in the cutting edge, internationally competitive research that investigates ways to manipulate and guide large ensembles of ultra-cold atoms and underpins future technological applications in ultra-high-precision metrology and sensors. Australia is currently moving into a prominent position amongst world leaders in this fast-paced research field. The o ....Controlled manipulation of matter-waves in atomic waveguiding structures. This project will enable Australian researchers to actively participate in the cutting edge, internationally competitive research that investigates ways to manipulate and guide large ensembles of ultra-cold atoms and underpins future technological applications in ultra-high-precision metrology and sensors. Australia is currently moving into a prominent position amongst world leaders in this fast-paced research field. The outcomes of this proposal will further raise the prestige of Australian research overseas, and lead to greater acceptance of Australia as a major player in fundamental research. It will also provide outstanding training opportunities for young researchers.Read moreRead less
Matter-wave vortices in engineered nanostructures. This project tackles some of the key problems which must be solved before any applications of manipulating and controlling Bose-Einstein condensates with nanostructures can be realised. This project is therefore of National Benefit for its advances in critical fundamental research and for the potential applications which may be ultimately derived from harnessing the power of this new state of matter. Australia is at the forefront of this revol ....Matter-wave vortices in engineered nanostructures. This project tackles some of the key problems which must be solved before any applications of manipulating and controlling Bose-Einstein condensates with nanostructures can be realised. This project is therefore of National Benefit for its advances in critical fundamental research and for the potential applications which may be ultimately derived from harnessing the power of this new state of matter. Australia is at the forefront of this revolution in quantum technology. This project furthers Australia's competitive position and opens up new opportunities for ground-breaking research and applications in an area which has the potential to be as revolutionary as the development of the laser.Read moreRead less
The development of inexpensive negatively charged films to increase the efficiency of commercial solar cells. This project aims to reduce the cost of solar electricity by developing inexpensive, negatively charged dielectric films. When deposited on the surfaces of commercial solar cells, these films will significantly increase cell efficiency, thereby producing more power from a given area.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100086
Funder
Australian Research Council
Funding Amount
$489,250.00
Summary
A platform for probing nanoscale magnetic states under multiple actuations. The proposed facility offers unique capabilities to investigate the interactions of spin with charge and lattice under external stimuli of light illumination, mechanical stress and voltage bias at various temperatures in a wide range of functional materials. Precise laser magnetometry and video-rate Kerr microscopy are integrated in a single magneto-optic Kerr effect (MOKE) system. This platform also aims to provide opti ....A platform for probing nanoscale magnetic states under multiple actuations. The proposed facility offers unique capabilities to investigate the interactions of spin with charge and lattice under external stimuli of light illumination, mechanical stress and voltage bias at various temperatures in a wide range of functional materials. Precise laser magnetometry and video-rate Kerr microscopy are integrated in a single magneto-optic Kerr effect (MOKE) system. This platform also aims to provide optical magnetic circular dichroism (OMCD) to assess electronic structures of semiconductors and biomedical materials. It will facilitate multidisciplinary research collaborations between academics and industries to advance next-generation spintronics, optoelectronics, energy conversion and storage, and biomedical technologies.Read moreRead less
Revealing the atoms that control performance in photoactive perovskites. This project aims to develop new electron microscopy techniques that will unambiguously determine the elusive structures of photoactive perovskite compounds under static and operational conditions, while correlating crystal structure with solar cell device performance. Photoactive perovskites are promising photovoltaic materials, however, many are sensitive to air and irradiation. This has impeded a huge international resea ....Revealing the atoms that control performance in photoactive perovskites. This project aims to develop new electron microscopy techniques that will unambiguously determine the elusive structures of photoactive perovskite compounds under static and operational conditions, while correlating crystal structure with solar cell device performance. Photoactive perovskites are promising photovoltaic materials, however, many are sensitive to air and irradiation. This has impeded a huge international research effort to determine their structure reliably at the atomic scale. With these new techniques applied to leading compounds and devices, it is expected this project will reveal the structural effects controlling electrical properties and device performance and so enable the design of superior perovskite photovoltaics.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101700
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Development of terahertz metamaterials based on III-V compound semiconductors. This project will involve the theoretical design and experimental realisation of III-V semiconductors based terahertz metamaterials, which exhibit unique electromagnetic responses. Such development is expected to significantly benefit novel applications in defence, sensing and communications. The outcomes of this project will expand the capability of the existing systems in efficient real-time control and manipulation ....Development of terahertz metamaterials based on III-V compound semiconductors. This project will involve the theoretical design and experimental realisation of III-V semiconductors based terahertz metamaterials, which exhibit unique electromagnetic responses. Such development is expected to significantly benefit novel applications in defence, sensing and communications. The outcomes of this project will expand the capability of the existing systems in efficient real-time control and manipulation of terahertz radiations.Read moreRead less
Quantum microscopy meets photovoltaics: new tools for solar cell research. This project aims to create an innovative platform to characterise solar cells, based on recently developed quantum diamond microscopy. It will enable direct imaging of the current flow in operating photovoltaic devices, providing a new window into key processes such as charge collection and recombination. The platform will be applied to a range of industry-relevant photovoltaic materials and devices. Anticipated outcomes ....Quantum microscopy meets photovoltaics: new tools for solar cell research. This project aims to create an innovative platform to characterise solar cells, based on recently developed quantum diamond microscopy. It will enable direct imaging of the current flow in operating photovoltaic devices, providing a new window into key processes such as charge collection and recombination. The platform will be applied to a range of industry-relevant photovoltaic materials and devices. Anticipated outcomes include new insights into recombination processes and the effect of device degradation, which could facilitate optimisation of the power conversion efficiency and reliability of next-generation solar cells. Additional benefits include new instruments and methods that may find use in the solar cell manufacturing industry.Read moreRead less