Nanowire infrared avalanche photodetectors towards single photon detection. This project aims to demonstrate semiconductor nanowire based infrared avalanche photodetectors (APDs) with ultra-high sensitivity towards single photon detection. By employing the advantages of their unique one-dimensional nanoscale geometry, the nanowire APDs can be engineered to different device architectures to achieve performance superior to their conventional counterparts. It is expected that this project will mak ....Nanowire infrared avalanche photodetectors towards single photon detection. This project aims to demonstrate semiconductor nanowire based infrared avalanche photodetectors (APDs) with ultra-high sensitivity towards single photon detection. By employing the advantages of their unique one-dimensional nanoscale geometry, the nanowire APDs can be engineered to different device architectures to achieve performance superior to their conventional counterparts. It is expected that this project will make significant contributions to the development of next generation high performance, fast speed, small size and low cost infrared photodetector technology platform enabling numerous emerging fields in modern transportation, communication, quantum computation and information processing to revolutionise our life and society.Read moreRead less
Unlocking exceptional properties through pressure-induced phase transitions. The aim of this project is to produce novel hybrid boron nitride materials by utilizing advanced green techniques of mechanochemistry and high-pressure methods to achieve a phase transition from hexagonal to wurtzite structure. The development of these materials is critical in tackling contemporary environmental and technological issues, particularly those linked to cooling systems in electronic devices and batteries. T ....Unlocking exceptional properties through pressure-induced phase transitions. The aim of this project is to produce novel hybrid boron nitride materials by utilizing advanced green techniques of mechanochemistry and high-pressure methods to achieve a phase transition from hexagonal to wurtzite structure. The development of these materials is critical in tackling contemporary environmental and technological issues, particularly those linked to cooling systems in electronic devices and batteries. The outcome of this study will be new nanomaterials with exceptional mechanical, thermal, and electronic properties, as well as new insights into mechanical-force induced green chemistry and an environmentally friendly synthesis process, and help with heat management, energy preservation, and advanced manufacturing.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100623
Funder
Australian Research Council
Funding Amount
$412,037.00
Summary
New electrodes for green electrochemical carbon dioxide capture. This project aims to develop new electrochemical carbon capture technology. By designing and fabricating new functional electrodes and high-performance electrochemical devices based on water and driven by renewable electricity, this project will enhance the ability to capture CO2, the primary greenhouse gas that causes global climate change. Expected outcomes include new multi-dimension electrodes with unique chemistry and state-of ....New electrodes for green electrochemical carbon dioxide capture. This project aims to develop new electrochemical carbon capture technology. By designing and fabricating new functional electrodes and high-performance electrochemical devices based on water and driven by renewable electricity, this project will enhance the ability to capture CO2, the primary greenhouse gas that causes global climate change. Expected outcomes include new multi-dimension electrodes with unique chemistry and state-of-the-art CO2 capture devices plus in-depth knowledge of electrochemical CO2 capture mechanisms for optimised device design and control. Benefits include the development of circular carbon economies with capabilities to effectively capture CO2, supporting Australian industries to achieve net zero emissions by 2050.Read moreRead less
A new in-situ structural measurement capability during nanoindentation. A new in-situ structural measurement capability during nanoindentation. This project aims to develop an in-situ Raman capability to obtain dynamic structural and mechanical behaviour of materials as a function of pressure during nanoindentation; and apply the new capability to directly monitor phase changes in silicon and germanium under pressure and correlate them with the simultaneous electrical responses. Anticipated outc ....A new in-situ structural measurement capability during nanoindentation. A new in-situ structural measurement capability during nanoindentation. This project aims to develop an in-situ Raman capability to obtain dynamic structural and mechanical behaviour of materials as a function of pressure during nanoindentation; and apply the new capability to directly monitor phase changes in silicon and germanium under pressure and correlate them with the simultaneous electrical responses. Anticipated outcomes are new instrumentation to directly probe the pressure-temperature phase diagram, and measure electrical properties of novel end phases in these semiconductors.Read moreRead less
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
Early Career Industry Fellowships - Grant ID: IE230100048
Funder
Australian Research Council
Funding Amount
$466,097.00
Summary
Ammonium-selective membranes to shift water industry into circular economy. The project aims to develop ammonium-selective membranes which are urgently needed in Australian key industries for sustainable ammonia recovery. The project expects to construct the membranes to achieve desirable pore size and surface functionality for fast and selective ammonia transport. The developed membranes should make ammonia recovery from wastewater more effective and sustainable, leading to the healthy waterway ....Ammonium-selective membranes to shift water industry into circular economy. The project aims to develop ammonium-selective membranes which are urgently needed in Australian key industries for sustainable ammonia recovery. The project expects to construct the membranes to achieve desirable pore size and surface functionality for fast and selective ammonia transport. The developed membranes should make ammonia recovery from wastewater more effective and sustainable, leading to the healthy waterway and reduced energy for both ammonia production and removal. Recovered ammonia expects to produce valuable products, supporting agriculture industry and hydrogen economy. The developed membranes should enable water industry's shift into circular economy, providing significant economic and environmental benefits to Australia.Read moreRead less
Probing and harnessing the light-matter interactions in two-dimensional phosphorene. This project aims to investigate phosphorene, a new two-dimensional material, for the development of new optical and electronic devices. Such materials have unique optical and electronic properties due to their flat physical structure, which gives rise to strong interactions between light and matter. The expected outcome of this project will be new kinds of near infrared light emitting diodes, single photon emit ....Probing and harnessing the light-matter interactions in two-dimensional phosphorene. This project aims to investigate phosphorene, a new two-dimensional material, for the development of new optical and electronic devices. Such materials have unique optical and electronic properties due to their flat physical structure, which gives rise to strong interactions between light and matter. The expected outcome of this project will be new kinds of near infrared light emitting diodes, single photon emitters and ground-breaking lasers. These developments will enable the fabrication of new low-power light sources that can integrate with communication technologies now, and quantum communication technologies in the future.Read moreRead less
Nanoscale heating towards high efficient nitrogen reduction reduction. This project aims to develop nanoscale heating technique using AC magnetic field for efficient synthesis of ammonia, widely used for fertiliser and having potential for hydrogen storage. This project is to introduce nanoscale heating concept by heating catalyst only but not solution in electrochemical catalysis to achieve high catalytic activity. Expected outcome is the creation of low cost catalysts having high selectivity a ....Nanoscale heating towards high efficient nitrogen reduction reduction. This project aims to develop nanoscale heating technique using AC magnetic field for efficient synthesis of ammonia, widely used for fertiliser and having potential for hydrogen storage. This project is to introduce nanoscale heating concept by heating catalyst only but not solution in electrochemical catalysis to achieve high catalytic activity. Expected outcome is the creation of low cost catalysts having high selectivity and formation rate for ammonia production. This unique technology has the potential to replace current ammonia production based on Haber-Bosch process, which consumes 2% of world energy and contributes 3% of overall CO2 emission. The project provides opportunities for new industries that will benefit Australian economy.Read moreRead less
Generating Highly Entangled Photons from Nonlinear Monolayer Domes. This project aims to investigate novel monolayer domes for the development of high-performance quantum photon sources. This research expects to expand our understanding of fundamental physics of photon pair generation in nonlinear optical materials. Such monolayer domes have ultra-high optical nonlinearity, which gives rise to strong light-matter interactions and enables high-efficiency photon pair generation. The expected outco ....Generating Highly Entangled Photons from Nonlinear Monolayer Domes. This project aims to investigate novel monolayer domes for the development of high-performance quantum photon sources. This research expects to expand our understanding of fundamental physics of photon pair generation in nonlinear optical materials. Such monolayer domes have ultra-high optical nonlinearity, which gives rise to strong light-matter interactions and enables high-efficiency photon pair generation. The expected outcome is demonstration of a prototype light-weight and intense quantum photon source based on novel materials, which can be readily integrated with photonic circuits for quantum communication technologies. This research could strengthen the development of new industries and lead to job creation.Read moreRead less
Swift heavy ion induced nano-porous antimony-based semiconductors. This project aims to study the fabrication and application of nano-porous antimony based semiconductors prepared by high-energy ion irradiation. Using a unique combination of synchrotron and laboratory- based analytical techniques as well as computer simulations, the project expects to identify the physical mechanisms for porous structure formation and exploit the materials for application in thermoelectric and thermo-photovoltai ....Swift heavy ion induced nano-porous antimony-based semiconductors. This project aims to study the fabrication and application of nano-porous antimony based semiconductors prepared by high-energy ion irradiation. Using a unique combination of synchrotron and laboratory- based analytical techniques as well as computer simulations, the project expects to identify the physical mechanisms for porous structure formation and exploit the materials for application in thermoelectric and thermo-photovoltaic devices. Expected outcomes of the project include fabrication processes compatible with current device fabrication methodologies that should enable rapid integration of the materials into advanced device applications. Significant benefits should result from novel applications of the technologies such as energy harvesting and sensor devices.Read moreRead less