Exciton-mediated room-temperature superconductivity . Superconductivity is the ability of an electronic material to conduct electrical current without resistance. This property underpins many existing and proposed technological applications, ranging from medical imaging to low-energy electronics and quantum computing. In this project, we aim to demonstrate a highly unconventional route towards superconductivity at room temperature and atmospheric pressure, by exploiting collective behaviour of e ....Exciton-mediated room-temperature superconductivity . Superconductivity is the ability of an electronic material to conduct electrical current without resistance. This property underpins many existing and proposed technological applications, ranging from medical imaging to low-energy electronics and quantum computing. In this project, we aim to demonstrate a highly unconventional route towards superconductivity at room temperature and atmospheric pressure, by exploiting collective behaviour of excitons (electron-hole pairs in a semiconductor) strongly coupled to photons. This research should help to overcome the biggest challenge for the widespread applications of superconductors: the very low temperature or extreme pressure that the superconducting materials need to function.Read moreRead less
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
A next generation 'smart' superconducting magnet system in persistent mode. Superconducting magnet devices use splicing, a process required to maintain the persistence of operation. Currently, the formation mechanism of splicing using magnesium diboride superconductor is complex and not technologically robust for industrial magnet manufacturing. This project aims to develop novel, reliable and economical superconducting splicing technologies that can produce an ultra-stable and uniform magnetic ....A next generation 'smart' superconducting magnet system in persistent mode. Superconducting magnet devices use splicing, a process required to maintain the persistence of operation. Currently, the formation mechanism of splicing using magnesium diboride superconductor is complex and not technologically robust for industrial magnet manufacturing. This project aims to develop novel, reliable and economical superconducting splicing technologies that can produce an ultra-stable and uniform magnetic field against unexpected power outages. Expected outcomes include the development of advanced green and cryogen free superconducting technologies, which would boost the Australian manufacturing industry through access to multi-billion-dollar global markets for power grids, medical imaging and energy generation and storage.Read moreRead less
Giant magnetic-thermoelectricity in topological materials . This project aims to explore magnetic field-induced exotic thermoelectricity in emerging topological materials and develop novel magnetic-field-mediated heat-to-electricity generators and coolers. The significance and outcomes of this project will be the discovery of new magnetic topological materials with thermoelectric conversion efficiency superior to traditional thermoelectric materials and unlocking the physics of the exotic magnet ....Giant magnetic-thermoelectricity in topological materials . This project aims to explore magnetic field-induced exotic thermoelectricity in emerging topological materials and develop novel magnetic-field-mediated heat-to-electricity generators and coolers. The significance and outcomes of this project will be the discovery of new magnetic topological materials with thermoelectric conversion efficiency superior to traditional thermoelectric materials and unlocking the physics of the exotic magnetic-field-correlated thermoelectric phenomena. The outcomes of this project will offer new avenues for novel applications of quantum topological materials and establish a solid foundation for the next generation of thermoelectric devices for various applications.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100192
Funder
Australian Research Council
Funding Amount
$458,318.00
Summary
Quantum sensing of magnetism in two dimensions. This project aims to use innovative quantum sensing technologies to investigate the novel emerging field of two-dimensional magnetism; imaging both static and dynamic forms of 2D magnetism. This project expects to generate new knowledge about magnetic van der Waals materials and their potential application to ultra-thin electronic and spintronic devices. Expected outcomes of this project are a deeper understanding of the formation and modulation of ....Quantum sensing of magnetism in two dimensions. This project aims to use innovative quantum sensing technologies to investigate the novel emerging field of two-dimensional magnetism; imaging both static and dynamic forms of 2D magnetism. This project expects to generate new knowledge about magnetic van der Waals materials and their potential application to ultra-thin electronic and spintronic devices. Expected outcomes of this project are a deeper understanding of the formation and modulation of magnetic order in 2D, new fabrication methods for deliberate domain wall formation, production of near-zero energy gap spin-waves, and new encapsulation methods for ultra-stable 2D materials. This should provide significant benefits towards fundamental physics and future device engineering. 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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100073
Funder
Australian Research Council
Funding Amount
$1,150,000.00
Summary
A femtosecond beamline for time-resolved momentum microscopy. This project aims to obtain a femtosecond high-harmonic generation beamline that will be integrated with a photoemission electron microscope to create Australia’s first time-resolved momentum microscope. This project expects to use ultrafast spectromicroscopy to observe the changes to the excited electron motion within materials after they absorb light. Expected outcomes of this project include improving our understanding of light-dri ....A femtosecond beamline for time-resolved momentum microscopy. This project aims to obtain a femtosecond high-harmonic generation beamline that will be integrated with a photoemission electron microscope to create Australia’s first time-resolved momentum microscope. This project expects to use ultrafast spectromicroscopy to observe the changes to the excited electron motion within materials after they absorb light. Expected outcomes of this project include improving our understanding of light-driven physical and chemical processes that occur in materials and optoelectronic devices. This should provide significant benefits through the development of new cost effective and efficient materials for energy harvesting, sensors and photocatalysts.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
Topological semiconductors resonate with an elusive form of radiation. The aims of the project are to fill a substantial knowledge gap in a class of novel semiconductors that can function as sensors in a frequency range where conventional semiconductors do not work. The way these materials interact with light is not fully understood. The project expects to provide this understanding of great significance and generate new knowledge in physics and materials science. Expected outcomes include a res ....Topological semiconductors resonate with an elusive form of radiation. The aims of the project are to fill a substantial knowledge gap in a class of novel semiconductors that can function as sensors in a frequency range where conventional semiconductors do not work. The way these materials interact with light is not fully understood. The project expects to provide this understanding of great significance and generate new knowledge in physics and materials science. Expected outcomes include a results database that will guide experiments and enable future sensor design. The project expects to provide substantial benefits by identifying the best materials for use as sensors in this frequency range, which has applications in communications, defence, and in the Science and Research Priorities of Food and Transport.Read moreRead less