High Quality Gallium Oxide for Power Electronics. This project aims to combine advanced nanocharacterisation techniques with complementary expertise in semiconductor growth to produce high-quality gallium oxide that will enable fabrication of high efficiency, cost-effective power electronics. These state-of-the-art devices are urgently required to significantly reduce power conversion losses to maximise the performance and benefits of electricity generation systems using renewable energy sources ....High Quality Gallium Oxide for Power Electronics. This project aims to combine advanced nanocharacterisation techniques with complementary expertise in semiconductor growth to produce high-quality gallium oxide that will enable fabrication of high efficiency, cost-effective power electronics. These state-of-the-art devices are urgently required to significantly reduce power conversion losses to maximise the performance and benefits of electricity generation systems using renewable energy sources. The availability of superior oxide materials with bespoke electrical properties will enable the construction of fast high-voltage electronic switches, converters and other components with enhanced performance and unique capabilities.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100739
Funder
Australian Research Council
Funding Amount
$354,958.00
Summary
Deterministic coherent diffractive imaging for the nanosciences. The technological trend towards nanoscale device fabrication demands picoscale measurements which will only be possible with the development of novel and advanced imaging techniques. This project will develop and implement cutting edge approaches to lensless imaging using both electrons and x-rays and will enable real-time imaging at the picoscale.
Discovery Early Career Researcher Award - Grant ID: DE150100791
Funder
Australian Research Council
Funding Amount
$373,536.00
Summary
Identification of optically efficient erbium centres in silicon. An efficient and economical light source, an essential component for silicon integrated photonics, is still missing. This project aims to identify optically efficient erbium centres in silicon materials that are compatible with the cost-effective silicon integration technology. This project also aims to advance the microscopic study of erbium in silicon to a single-atom level and establish the essential link for optimising light em ....Identification of optically efficient erbium centres in silicon. An efficient and economical light source, an essential component for silicon integrated photonics, is still missing. This project aims to identify optically efficient erbium centres in silicon materials that are compatible with the cost-effective silicon integration technology. This project also aims to advance the microscopic study of erbium in silicon to a single-atom level and establish the essential link for optimising light emission between the microscopic structure and the optical transition. The expected outcomes are optically efficient erbium centres in silicon, which will speed up the material optimisation process and advance the development of silicon integrated photonics in Australia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100150
Funder
Australian Research Council
Funding Amount
$595,280.00
Summary
Advanced multifunctional photoelectron spectroscopy platform. This project aims to establish a new integrated facility that will allow researchers to characterise the surface structure and electronic properties of materials, which is essential for a complete understanding of their functionality. The development of the next generation of electronic, optical, and biomedical devices requires new materials with properties optimised for the particular application. This facility, to be housed in state ....Advanced multifunctional photoelectron spectroscopy platform. This project aims to establish a new integrated facility that will allow researchers to characterise the surface structure and electronic properties of materials, which is essential for a complete understanding of their functionality. The development of the next generation of electronic, optical, and biomedical devices requires new materials with properties optimised for the particular application. This facility, to be housed in state-of-the-art laboratories and managed as an open access resource, will meet the needs of a large number of innovative projects and enable advances in many fields including electronics, nanotechnology, solar energy, biotechnology and advanced materials.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL160100089
Funder
Australian Research Council
Funding Amount
$2,600,796.00
Summary
In situ electron microscopy toward new materials and applications. In situ electron microscopy toward new materials and applications. This project aims to develop materials for structural and green energy applications, using spatially-resolved, dynamic in situ transmission electron microscopy to research fundamental mechanical, electrical, thermal, optical, optoelectronic and photovoltaic properties of diverse nanostructures. These techniques measure nanomaterial (one-dimensional nanotubes and n ....In situ electron microscopy toward new materials and applications. In situ electron microscopy toward new materials and applications. This project aims to develop materials for structural and green energy applications, using spatially-resolved, dynamic in situ transmission electron microscopy to research fundamental mechanical, electrical, thermal, optical, optoelectronic and photovoltaic properties of diverse nanostructures. These techniques measure nanomaterial (one-dimensional nanotubes and nanowires and two-dimensional graphene-like nanosheets) response to external stimuli, including mechanical, electrical, optical and thermal stimuli. Anticipated outcomes are new ultralight and superstrong structural composites and ‘green-energy’ nanomaterials, such as solar cells, touch panels, batteries, supercapacitors, field-effect transistors, light sensors and displays.Read moreRead less
Enabling semiconductor nanowire technologies via 3D atomic-scale insight. Semiconductor nanowires (NWs) are nanotechnology building blocks that have the potential to transform solar cells, light emitting diodes, lasers and transistors, creating new industries in communications, energy and healthcare. The industrial development of NWs has been blocked by uncertainties in the relationships between their growth conditions, properties and atomic-scale structure. This project will address this chall ....Enabling semiconductor nanowire technologies via 3D atomic-scale insight. Semiconductor nanowires (NWs) are nanotechnology building blocks that have the potential to transform solar cells, light emitting diodes, lasers and transistors, creating new industries in communications, energy and healthcare. The industrial development of NWs has been blocked by uncertainties in the relationships between their growth conditions, properties and atomic-scale structure. This project will address this challenge by establishing a rigorous framework for these relationships. The project aims to achieve this by harnessing the unique power of atom probe microscopy to reveal the NW structure in three dimensions, and at atomic-resolution. The project aims to place Australian research at the frontier of development of these future industries.Read moreRead less
Making every electron count in atomic resolution microscopy. The development of aberration-corrected electron microscopy, which allows individual atom imaging with unprecedented precision, was recognised by the 2011 Wolf Prize in Physics. However, only a very limited amount of the wealth of information obtainable from such microscopes is currently exploited. By collecting a maximal data set of electrons scattered in manifold different ways and using the fundamental theory of electron-specimen in ....Making every electron count in atomic resolution microscopy. The development of aberration-corrected electron microscopy, which allows individual atom imaging with unprecedented precision, was recognised by the 2011 Wolf Prize in Physics. However, only a very limited amount of the wealth of information obtainable from such microscopes is currently exploited. By collecting a maximal data set of electrons scattered in manifold different ways and using the fundamental theory of electron-specimen interaction, this project will realise the huge potential of this untapped data. This will improve the utility of scanning transmission electron microscopy far beyond its current level. Applying these new techniques will expand our understanding of the structure and function of advanced materials.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100320
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Increasing efficiency in tandem silicon-perovskite solar cells. This project aims to increase the efficiency of silicon solar cells. Organo-halide perovskites semiconductors will improve crystalline silicon’s single-junction solar cell efficiency from its current ~25% record to the theoretical limit of 30% at an affordable cost for the market. This project will integrate organo-halide perovskite semiconductors with silicon cells in a tandem solar cell, a structure that harvests sunlight more eff ....Increasing efficiency in tandem silicon-perovskite solar cells. This project aims to increase the efficiency of silicon solar cells. Organo-halide perovskites semiconductors will improve crystalline silicon’s single-junction solar cell efficiency from its current ~25% record to the theoretical limit of 30% at an affordable cost for the market. This project will integrate organo-halide perovskite semiconductors with silicon cells in a tandem solar cell, a structure that harvests sunlight more efficiently. This project should lead to the development of solar cells with state-of-the-art efficiencies greater than 30% at an affordable cost for the energy market.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100118
Funder
Australian Research Council
Funding Amount
$1,800,000.00
Summary
UltraTEM: Resolving the structure of matter in space, energy and time. This project aims to establish a transmission electron microscope facility to analyse materials structure at the atomic level. A small number of atoms in critical locations governs the properties of materials from solar cells and catalysts to aerospace alloys, bio-sensors and quantum computers. To understand and engineer matter at this atomic level, tools are needed to characterise these critical atoms. This open access, nati ....UltraTEM: Resolving the structure of matter in space, energy and time. This project aims to establish a transmission electron microscope facility to analyse materials structure at the atomic level. A small number of atoms in critical locations governs the properties of materials from solar cells and catalysts to aerospace alloys, bio-sensors and quantum computers. To understand and engineer matter at this atomic level, tools are needed to characterise these critical atoms. This open access, national facility will be able to characterise matter at the atomic-level. Expected outcomes include better understanding of the natural world and advanced materials to solve problems in energy, technology, health, environment, communications, advanced manufacturing, transport and security.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100132
Funder
Australian Research Council
Funding Amount
$1,486,000.00
Summary
A triple beam microscope: new frontiers in materials nanocharacterisation. This project aims to establish a triple beam ion and electron microscope facility for the modification, preparation and characterisation of materials that have hitherto been too sensitive for high resolution analysis with charged particle beams. It is expected that materials will be studied artefact-free and at the nanoscale with twin ion beams and new detectors that allow novel imaging modes and extreme chemical sensitiv ....A triple beam microscope: new frontiers in materials nanocharacterisation. This project aims to establish a triple beam ion and electron microscope facility for the modification, preparation and characterisation of materials that have hitherto been too sensitive for high resolution analysis with charged particle beams. It is expected that materials will be studied artefact-free and at the nanoscale with twin ion beams and new detectors that allow novel imaging modes and extreme chemical sensitivity plus controlled atmosphere transfer to other instruments for correlative measurements. This unique facility should benefit research in many disciplines such as physics, chemistry, geology, pharmacy, materials, civil and chemical engineering by allowing first-ever observations of vital phenomena in diverse materials.Read moreRead less