Braiding Dynamics of Majorana Modes. The project aims to investigate Majorana modes, exotic quantum particles which can be found in the new material class of Topological Superconductivity. In particular, they can be utilised to construct fault-tolerant quantum bits. Quantum logic gates are enabled by moving these Majorana modes around each other, i.e., by braiding them, leading to an error-free quantum performance. This project will deliver cutting-edge simulations to analyse the braiding proces ....Braiding Dynamics of Majorana Modes. The project aims to investigate Majorana modes, exotic quantum particles which can be found in the new material class of Topological Superconductivity. In particular, they can be utilised to construct fault-tolerant quantum bits. Quantum logic gates are enabled by moving these Majorana modes around each other, i.e., by braiding them, leading to an error-free quantum performance. This project will deliver cutting-edge simulations to analyse the braiding process in condensed matter systems and benchmark how these fault-tolerant quantum bits operate under real-world conditions. By providing the theory for advanced structures and devices, this project will inform experiments and pave the way for future technology based on topological phenomena.Read moreRead less
Kagome metals: From Japanese basket to next generation electronic devices. This project aims to investigate a new material that is very promising for electronic devices that can operate faster, and be more energy efficient than today’s silicon-based technology. Kagome metals have topological non-trivial nature and can pass current without resistance, making them ideal for next-generation electronic devices. This project aims to grow Kagome metals in the ultra-thin layers needed to realise this p ....Kagome metals: From Japanese basket to next generation electronic devices. This project aims to investigate a new material that is very promising for electronic devices that can operate faster, and be more energy efficient than today’s silicon-based technology. Kagome metals have topological non-trivial nature and can pass current without resistance, making them ideal for next-generation electronic devices. This project aims to grow Kagome metals in the ultra-thin layers needed to realise this potential, make devices and study their electronic properties. Expected outcomes of the project will include showing Kagome metals can form the basis of ultra-low energy electronic devices, as well as having future applications in high-temperature fault-tolerant quantum computing.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL230100176
Funder
Australian Research Council
Funding Amount
$2,920,000.00
Summary
Computational design of frontier materials for sustainable technologies. This Laureate will establish a new and powerful computational materials research platform that uses cutting-edge ab initio calculations and artificial intelligence, to understand and design tailored structures that possess the required new and improved functionalities for tomorrow’s materials. In enabling the development of novel catalysts needed for the generation of green fuels and chemicals, and key quantum devices for q ....Computational design of frontier materials for sustainable technologies. This Laureate will establish a new and powerful computational materials research platform that uses cutting-edge ab initio calculations and artificial intelligence, to understand and design tailored structures that possess the required new and improved functionalities for tomorrow’s materials. In enabling the development of novel catalysts needed for the generation of green fuels and chemicals, and key quantum devices for quantum technologies, this Laureate promises timely support for Australia’s commitment to renewable energies, low emissions and its nascent quantum future. New and existing collaboration with leading international groups underpin significant national benefits including new disciplinary capacity and world-class research.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100235
Funder
Australian Research Council
Funding Amount
$180,000.00
Summary
Interfacial mapping facility. New electronic materials and devices impact on everyday life in areas such as photovoltaics, biotechnology and healthcare. This facility will provide researchers with the unique capability of mapping both the structure and electronic properties of materials on the nanoscale. It will be an essential tool for developing new electronics based on nanotechnology.
Atomic-Scale Engineering of Bioactive Organic Molecules on Surfaces. Advances in scanning probe microscopy (SPM) have enabled the precise engineering of matter at surfaces. The ability to image and track changes at surfaces is simply staggering, but the frontier of molecules with pharmaceutical and agrichemical importance remains unexplored. This interdisciplinary project aims to synthesise fundamental molecules and reveal molecular rearrangement pathways utilising SPM. Expected outcomes of this ....Atomic-Scale Engineering of Bioactive Organic Molecules on Surfaces. Advances in scanning probe microscopy (SPM) have enabled the precise engineering of matter at surfaces. The ability to image and track changes at surfaces is simply staggering, but the frontier of molecules with pharmaceutical and agrichemical importance remains unexplored. This interdisciplinary project aims to synthesise fundamental molecules and reveal molecular rearrangement pathways utilising SPM. Expected outcomes of this project include new methods to couple molecules otherwise unobtainable by traditional means and fundamental knowledge of molecular manipulation and chemical structure. This aims to provide significant benefits, such as the translation of new chemical principles to academic and industrial laboratories.Read moreRead less
Controllable quantum phases in two-dimensional metal-organic nanomaterials. This project aims to design novel two-dimensional metal-organic nanomaterials and to control electronic quantum phases therein. The project expects to generate new fundamental knowledge in advanced materials, solid-state physics and quantum nanoscience. It will rely on supramolecular chemistry to synthesise new atomically precise functional materials. Expected outcomes include the fabrication of new advanced nanomaterial ....Controllable quantum phases in two-dimensional metal-organic nanomaterials. This project aims to design novel two-dimensional metal-organic nanomaterials and to control electronic quantum phases therein. The project expects to generate new fundamental knowledge in advanced materials, solid-state physics and quantum nanoscience. It will rely on supramolecular chemistry to synthesise new atomically precise functional materials. Expected outcomes include the fabrication of new advanced nanomaterials, as well as the observation and control of new quantum phenomena therein. The project should provide significant benefits, such as advancing basic research in quantum nanomaterials, and aiding to lay the foundation for next-generation electronics and information technologies.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170101170
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Electronic structure on both sides of the Fermi level in molecular material. This project aims to develop an inverse photoemission spectrometer to elucidate the electronic properties of molecular materials. In tandem with traditional photoemission, the spectrometer will measure the electronic structure of small molecules for organic electronics and two-dimensional graphene-analogous polymers, providing information critical to their development and use. The instrument is expected to bring critica ....Electronic structure on both sides of the Fermi level in molecular material. This project aims to develop an inverse photoemission spectrometer to elucidate the electronic properties of molecular materials. In tandem with traditional photoemission, the spectrometer will measure the electronic structure of small molecules for organic electronics and two-dimensional graphene-analogous polymers, providing information critical to their development and use. The instrument is expected to bring critical insight to the burgeoning field of molecular materials, with potential widespread applications from energy conversion to sensing and electronics, with benefits across sectors.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668510
Funder
Australian Research Council
Funding Amount
$180,240.00
Summary
Nanostructure Deposition Facility. New electronic devices and materials that exploit the properties of nanostructured surfaces are predicted to have a major impact on everyday life in areas such as information technology, biotechnology and healthcare. The Nanostructure Deposition Facility (NDF) is a unique facility, providing access to the highly specialised deposition equipment required to fabricate these important nanostructured surfaces from a variety of materials. The NFDL represents a major ....Nanostructure Deposition Facility. New electronic devices and materials that exploit the properties of nanostructured surfaces are predicted to have a major impact on everyday life in areas such as information technology, biotechnology and healthcare. The Nanostructure Deposition Facility (NDF) is a unique facility, providing access to the highly specialised deposition equipment required to fabricate these important nanostructured surfaces from a variety of materials. The NFDL represents a major new joint venture between seven Australian institutions and will provide these researchers with the essential tools for developing new electronic devices, biosensors, detectors and solar cells based on nanotechnology.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.