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Diamond membranes for advanced manufacturing. This project aims to unlock the potential of diamond membrane devices in research and industry, by enabling the scalable manufacture of high quality diamond membrane samples. These will be packaged in a form that is easily transportable and with properties that are optimizable and functional for a variety of end-users. This project will allow the distribution of high quality base material to the academic and start-up markets. The expected outcome inc ....Diamond membranes for advanced manufacturing. This project aims to unlock the potential of diamond membrane devices in research and industry, by enabling the scalable manufacture of high quality diamond membrane samples. These will be packaged in a form that is easily transportable and with properties that are optimizable and functional for a variety of end-users. This project will allow the distribution of high quality base material to the academic and start-up markets. The expected outcome includes the development of products in healthcare and security such as infra-red frequency combs for gas-based chemical sensing and nanopore devices for new DNA sequencers.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101157
Funder
Australian Research Council
Funding Amount
$384,276.00
Summary
Realisation of novel electronic phases in two-dimensional materials. This project will address one of the most pressing concerns facing society today, the efficient generation, storage, transmission and use of energy. Silicon based transistor technology is approaching the hard limit of efficiency set by thermodynamics, requiring new materials to be found that possess electronic properties that break away from conventional transistor technology. Utilising a new facility being installed by the app ....Realisation of novel electronic phases in two-dimensional materials. This project will address one of the most pressing concerns facing society today, the efficient generation, storage, transmission and use of energy. Silicon based transistor technology is approaching the hard limit of efficiency set by thermodynamics, requiring new materials to be found that possess electronic properties that break away from conventional transistor technology. Utilising a new facility being installed by the applicant at the Australian Synchrotron, this project aims to prepare and characterise the electronic properties of free-standing atomically thin bismuth. Successful realisation of this project will provide a radical new approach towards realising more efficient electronic devices for the storage and transmission of energy.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL130100171
Funder
Australian Research Council
Funding Amount
$2,863,442.00
Summary
Computers of the future: atomic-scale logic. Building upon internationally recognised leadership in the development of atomic-scale electronic devices, this project aims to achieve the ultimate in computer miniaturisation: to develop components for the world's first integrated circuit, where all elements are constructed on the atomic scale.
Quantum Design of Majorana Modes in Magnet-Superconductor Hybrid Systems. This project will identify magnet-superconductor hybrid structures which feature topological superconductivity, a new material class which promises to revolutionise future technology. By performing cutting-edge transport calculations, this project will also predict signatures of topological superconductors for ongoing and future experiments. Expected outcomes of this project include identification of suitable candidate mat ....Quantum Design of Majorana Modes in Magnet-Superconductor Hybrid Systems. This project will identify magnet-superconductor hybrid structures which feature topological superconductivity, a new material class which promises to revolutionise future technology. By performing cutting-edge transport calculations, this project will also predict signatures of topological superconductors for ongoing and future experiments. Expected outcomes of this project include identification of suitable candidate materials and protocols for the quantum design of prototype devices. By providing the theory of advanced structures and devices, this project will inform experiments and pave the way for future technology based on topological phenomena.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100060
Funder
Australian Research Council
Funding Amount
$370,000.00
Summary
Year-round accessible angle-resolved photoemission spectroscopy facility . Year-round accessible angle-resolved photoemission spectroscopy facility: This project aims to create a year-round readily accessible facility for angle-resolved photoemission spectroscopy combined with in situ scanning tunnelling microscopy, cementing Australia's leadership position in novel electronic materials research. The facility is the first of its kind in Australia, housed at the Australian Synchrotron, and access ....Year-round accessible angle-resolved photoemission spectroscopy facility . Year-round accessible angle-resolved photoemission spectroscopy facility: This project aims to create a year-round readily accessible facility for angle-resolved photoemission spectroscopy combined with in situ scanning tunnelling microscopy, cementing Australia's leadership position in novel electronic materials research. The facility is the first of its kind in Australia, housed at the Australian Synchrotron, and accessible to a broad user base. The facility will be an essential tool for study of new electronic materials such as graphene, two-dimensional semiconductors, topological insulators, and superconductors. This research aims to lead to new thermoelectric, photovoltaic, superconducting, and computing devices, revolutionising the generation, transfer, storage, and use of electrical energy.Read moreRead less
Tailored quantum structures. Using real-time movies, the project will image how quantum structures form and tailor their electronic properties by controlling their shape. Such designer nanostructures have potential applications in optoelectronics, quantum computing and quantum cryptography.
Investigating the behaviour of semiconductor materials under extreme pressures. The study of materials at extreme pressures is important and interesting from both a technological and a fundamental perspective. This project will significantly advance the understanding of how semiconductors react to high-pressure environments by exploiting new and innovative approaches to both the application of the extreme pressure and the in-situ measurement of the resultant structures. It will establish a compr ....Investigating the behaviour of semiconductor materials under extreme pressures. The study of materials at extreme pressures is important and interesting from both a technological and a fundamental perspective. This project will significantly advance the understanding of how semiconductors react to high-pressure environments by exploiting new and innovative approaches to both the application of the extreme pressure and the in-situ measurement of the resultant structures. It will establish a comprehensive understanding of the deformation behaviour of semiconductors that will be essential in the search for advanced materials with entirely new properties that may be useful in semiconducting device applications.Read moreRead less
Back to the future: making atomic-scale high-speed germanium transistors. This project links scientists from Australia and Italy to develop atomic-scale devices in the germanium material. By exploiting the unique properties of this material and its integration with silicon, faster and smaller transistors will be developed.
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.
Discovery Early Career Researcher Award - Grant ID: DE190100336
Funder
Australian Research Council
Funding Amount
$416,899.00
Summary
Superconducting diamond for investigating sources of interface noise. This project aims to identify and eliminate the sources of electro-magnetic noise at material interfaces, through the development of diamond as a model semiconductor/superconductor material system. The project expects to generate new understandings about the origin of these noise sources, using a combination of new nanofabrication developments and exquisite control over the surface chemical bonding of the diamond material. Exp ....Superconducting diamond for investigating sources of interface noise. This project aims to identify and eliminate the sources of electro-magnetic noise at material interfaces, through the development of diamond as a model semiconductor/superconductor material system. The project expects to generate new understandings about the origin of these noise sources, using a combination of new nanofabrication developments and exquisite control over the surface chemical bonding of the diamond material. Expected outcomes include enhanced understanding and control of noise sources in superconducting and quantum devices, and potentially a new material platform for the creation of superconducting quantum circuits. By supporting Australia's nascent quantum technologies industry this project will help support research training and a higher quality workforce, with the possibility for enabling job creation in the future.Read moreRead less