Hot Topic: Quantum Design of Phononic Heat Filters. Heat management is critical to many technologies for sustainable energy, electronics, protective equipment and energy-efficient buildings. The phonon is the quantum particle representing a travelling vibration and is responsible for the transmission of heat in solids. This project will study the new mechanisms for phonon transport in solids modified with embedded nanoparticles, which operate as phononic filters. Neutron spectroscopy provides a ....Hot Topic: Quantum Design of Phononic Heat Filters. Heat management is critical to many technologies for sustainable energy, electronics, protective equipment and energy-efficient buildings. The phonon is the quantum particle representing a travelling vibration and is responsible for the transmission of heat in solids. This project will study the new mechanisms for phonon transport in solids modified with embedded nanoparticles, which operate as phononic filters. Neutron spectroscopy provides a tool to measure the phonon density of states which is critical for developing a mathematical model of thermal boundary resistance. This is expected to identify mechanisms for ultra-low thermal conductivity leading to potential applications in thermoelectric generators and heat-resistant materials.Read moreRead less
Magnonics with skyrmions. Skyrmions – nanoscale topologically protected spin textures, are considered as ideal candidates for encoding and transmitting bits of information. This burgeoning research field, however, suffers from the same limitations of all spintronic concepts – the high currents needed to move skyrmions. Magnonics is yet another emerging approach, which main aim is to investigate the behaviour of spin waves in magnetic nanostructures. In essence, spin waves are a propagating re-or ....Magnonics with skyrmions. Skyrmions – nanoscale topologically protected spin textures, are considered as ideal candidates for encoding and transmitting bits of information. This burgeoning research field, however, suffers from the same limitations of all spintronic concepts – the high currents needed to move skyrmions. Magnonics is yet another emerging approach, which main aim is to investigate the behaviour of spin waves in magnetic nanostructures. In essence, spin waves are a propagating re-ordering of the magnetisation and therefore use the least amount of power, making them perfect for driving skyrmions. This project fuses skyrmions with magnonics. The central goal is the formulation of model for the magnon assisted manipulation of skyrmions and their lattices.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220101147
Funder
Australian Research Council
Funding Amount
$407,600.00
Summary
First-principles design of atomic defects for quantum technologies. This project aims to address the issue of designing and engineering better single-photon sources based on atomic defects in solids, a crucial building block for many quantum technologies. Using advanced first-principles quantum mechanical theories and calculations, the project expects to produce fundamental knowledge of key mechanisms and properties, and to use this to inform the design of new atomic defects for tailored applica ....First-principles design of atomic defects for quantum technologies. This project aims to address the issue of designing and engineering better single-photon sources based on atomic defects in solids, a crucial building block for many quantum technologies. Using advanced first-principles quantum mechanical theories and calculations, the project expects to produce fundamental knowledge of key mechanisms and properties, and to use this to inform the design of new atomic defects for tailored applications as quantum emitters. The expected outcomes, including novel methodologies, will contribute to different research areas, from condensed matter and materials physics to quantum science and technology. This project should provide significant benefits in accelerating quantum technology innovation in Australia.Read moreRead less
From One Structure to Another for Improved Materials Design. This project aims to characterise a new way of generating strengthening precipitate structures for lightweight aluminium alloys. Precipitation in the solid state is key to the performance of many materials, but is especially important for light alloys used in structural applications. This project expects to deliver greater fundamental understanding of precipitation mechanisms and generate experimental and computational methods for thre ....From One Structure to Another for Improved Materials Design. This project aims to characterise a new way of generating strengthening precipitate structures for lightweight aluminium alloys. Precipitation in the solid state is key to the performance of many materials, but is especially important for light alloys used in structural applications. This project expects to deliver greater fundamental understanding of precipitation mechanisms and generate experimental and computational methods for three-dimensional characterisation and simulations at the atomic-scale of embedded nanostructures. This should provide significant benefits for the improved design of light alloys, such as for the automotive and aerospace sectors, but also for high-tech materials whose function depends on precipitates. Read moreRead less
Enlightening single rare-earth atoms in scanning-tunnelling microscopy. This project aims to create a tool to systematically engineer optical properties of emitters in solids by understanding and manipulating materials atom by atom. The tool – an optically enhanced scanning tunnelling microscope – is expected to drive future developments in optical technologies. The project expects to deliver an atomic-scale understanding of rare-earth sites optimised for sensing and coherence. The expected outc ....Enlightening single rare-earth atoms in scanning-tunnelling microscopy. This project aims to create a tool to systematically engineer optical properties of emitters in solids by understanding and manipulating materials atom by atom. The tool – an optically enhanced scanning tunnelling microscope – is expected to drive future developments in optical technologies. The project expects to deliver an atomic-scale understanding of rare-earth sites optimised for sensing and coherence. The expected outcomes include highly developed theoretical insights into solid-state emitters and how to control their interactions with light and other fields. The expected benefit based on the ability to engineer optimised emitters for optical sensors and quantum technologies will transform material science from exploration to design.Read moreRead less
Design and Fabrication of 2D Hybrid Materials. There are >300 2D materials like graphene with potentially exotic and useful electrooptic and superconductor properties that will drive novel industrial applications. This project aims to use advanced computational and experimental techniques to discover and fabricate new 2D hybrid materials built from different layers of 2D materials. This approach is essential as the number of possible hybrids is huge (millions) and current processes to identify a ....Design and Fabrication of 2D Hybrid Materials. There are >300 2D materials like graphene with potentially exotic and useful electrooptic and superconductor properties that will drive novel industrial applications. This project aims to use advanced computational and experimental techniques to discover and fabricate new 2D hybrid materials built from different layers of 2D materials. This approach is essential as the number of possible hybrids is huge (millions) and current processes to identify and build 2D hybrids are technically challenging and slow. Expected outcomes include defining a new paradigm for efficient identification and synthesis of 2D hybrids with exotic, bespoke properties. The generation of a large database of materials for researchers/industry would be of wide benefit.Read moreRead less
Topological superconductivity and spin electronics in silicon and germanium. This project will exploit recent breakthroughs in materials growth, theoretical physics and micromagnet technology to design and build a new platform for future quantum devices and topological quantum computers. Instead of using exotic materials, we will fabricate hybrid superconductor-semiconductor devices with conventional silicon and germanium semiconductors, using the same nanofabrication techniques that industry us ....Topological superconductivity and spin electronics in silicon and germanium. This project will exploit recent breakthroughs in materials growth, theoretical physics and micromagnet technology to design and build a new platform for future quantum devices and topological quantum computers. Instead of using exotic materials, we will fabricate hybrid superconductor-semiconductor devices with conventional silicon and germanium semiconductors, using the same nanofabrication techniques that industry uses to create integrated circuits. The outcome will be an entirely new approach to hosting topological modes, in an architecture that can be scaled to make topological based qubits, using industrially compatible semiconductors. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100144
Funder
Australian Research Council
Funding Amount
$411,000.00
Summary
Rational design of light-emitting materials for lighting and displays. This project aims to solve the most pressing problem in organic light emitting diodes - the lack of highly efficient, phosphorescent blue emitters. The project expects to generate new understanding of energy loss mechanisms in such devices from multiscale quantum mechanical models, which describe the interaction of the emitter with its environment, and to design new materials via big data approaches. Expected outcomes include ....Rational design of light-emitting materials for lighting and displays. This project aims to solve the most pressing problem in organic light emitting diodes - the lack of highly efficient, phosphorescent blue emitters. The project expects to generate new understanding of energy loss mechanisms in such devices from multiscale quantum mechanical models, which describe the interaction of the emitter with its environment, and to design new materials via big data approaches. Expected outcomes include a fundamental understanding of non-radiative decay processes in organometallic complexes and more efficient lighting and display technologies. This project should provide significant benefits in reducing energy use, as lighting and displays consume around a quarter of the energy generated in developed countries.Read moreRead less
Exploiting shear to form new structures of carbon. This project aims to create new, technologically-interesting, materials by combining shear (sliding forces) with high pressure. The work will use both modelling and experiments to understand the pathways to form new materials such as a different form of diamond that is predicted to be harder than regular diamond. Such a material could be used in coatings for cutting tools or ultra-low-scratch surfaces. Expected outcomes include both an understan ....Exploiting shear to form new structures of carbon. This project aims to create new, technologically-interesting, materials by combining shear (sliding forces) with high pressure. The work will use both modelling and experiments to understand the pathways to form new materials such as a different form of diamond that is predicted to be harder than regular diamond. Such a material could be used in coatings for cutting tools or ultra-low-scratch surfaces. Expected outcomes include both an understanding of the importance of shear in the study of high-pressure science, and as a tool to manufacture new functional materials.Read moreRead less
Information transfer in topological matter: how relativity speeds up memory. In the 21st century our economy and security rely on fast information processing, which requires state-of-the-art computer memory. Emerging memory technologies rely on magnets, which retain data during power outages and switch faster than currently used semiconductor devices. This Fellowship will establish a breakthrough paradigm for ultra-fast information processing using magnets and newly-discovered topological materi ....Information transfer in topological matter: how relativity speeds up memory. In the 21st century our economy and security rely on fast information processing, which requires state-of-the-art computer memory. Emerging memory technologies rely on magnets, which retain data during power outages and switch faster than currently used semiconductor devices. This Fellowship will establish a breakthrough paradigm for ultra-fast information processing using magnets and newly-discovered topological materials. It will develop a computational tool to enhance the switching rate of devices incorporating topological materials that emulate industry blueprints for memory building blocks. If successful, it will vastly improve the speed and functionality of computer memory, logic elements, artificial intelligence devices and sensors.Read moreRead less