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
Electronic functionality in nanoscale materials: from discovery to design. This project will develop innovative multifunctional carbon/boron-nitride nanomaterials by devising new strategies to manipulate their electronic functionality. Outcomes will include technological breakthroughs leading to smart materials for energy storage, greenhouse gas emission reduction and nanoelectronics.
The bad metallic state in quantum materials. The project seeks to elucidate how an important quantum state of matter emerges from strong interactions between electrons. Quantum materials are a diverse class of materials whose unusual properties emerge from the strong interactions between electrons. Many have metallic phases with a low electrical conductivity (bad metals). The aim is to understand and characterise this quantum state of matter and how it emerges from the constituent electrons. An ....The bad metallic state in quantum materials. The project seeks to elucidate how an important quantum state of matter emerges from strong interactions between electrons. Quantum materials are a diverse class of materials whose unusual properties emerge from the strong interactions between electrons. Many have metallic phases with a low electrical conductivity (bad metals). The aim is to understand and characterise this quantum state of matter and how it emerges from the constituent electrons. An expected outcome will be falsification of specific theoretical models (based on techniques from string theory) and development of concepts that can be used to interpret experiments, including on ultra-cold atomic gases. Projected future benefits include new insights and concepts that may aid the design and synthesis of new materials for applications based on superconductivity, thermoelectricity and magnetoresistance.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
Beyond the standard model of organic quantum spin liquids. This project aims to apply new insights about the magnetic interactions in molecular crystals to model their emergent quantum behaviours via state-of-the-art analytical and computational methods. It will focus on organic charge transfer salts that exhibit superconductivity, multiferroicity, and quantum spin liquids, as a result of the strong interactions between electrons. This will provide new approaches to modelling the electronic and ....Beyond the standard model of organic quantum spin liquids. This project aims to apply new insights about the magnetic interactions in molecular crystals to model their emergent quantum behaviours via state-of-the-art analytical and computational methods. It will focus on organic charge transfer salts that exhibit superconductivity, multiferroicity, and quantum spin liquids, as a result of the strong interactions between electrons. This will provide new approaches to modelling the electronic and magnetic properties of structurally complex materials. Many have widespread potential for applications, such as electricity transport, thermoelectric refrigeration, field sensing, spintronics, and in future classical and quantum computers.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
Trouble at the bottom: exploring the limits of Fermi liquid theory through dimensionless ratios. Ratios allow us to understand how big we expect something to be. This project will discover new ratios in materials that are difficult to understand, but have remarkable properties that could lead to dramatic new technologies if we understood them better.
Quantum many-body theory of electrical and thermal transport properties of strongly correlated electron materials. New advanced electronic materials conduct heat and electricity via novel mechanisms that must be described via quantum theory. Understanding and modelling these material properties may lead to design of better materials for use in environmentally friendly refrigerators and power generators that do not require mechanical parts.
ARC Centre of Excellence for Engineered Quantum Systems. The future of technology lies in controlling the quantum world. The ARC Centre of Excellence for Engineered Quantum Systems (EQuS) will deliver the building blocks of future quantum technologies and, critically, ensure Australian primacy in this endeavour. Three strategic research programs will target Quantum Measurement and Control; Synthetic Quantum Systems and Simulation; and Quantum-Enabled Sensors and Metrology. Within these programs, ....ARC Centre of Excellence for Engineered Quantum Systems. The future of technology lies in controlling the quantum world. The ARC Centre of Excellence for Engineered Quantum Systems (EQuS) will deliver the building blocks of future quantum technologies and, critically, ensure Australian primacy in this endeavour. Three strategic research programs will target Quantum Measurement and Control; Synthetic Quantum Systems and Simulation; and Quantum-Enabled Sensors and Metrology. Within these programs, our Centre will exploit the deepest principles and resources of quantum physics to solve specific problems in engineering, chemistry biology and medicine, stimulating the Australian scientific and engineering communities to exploit (and benefit from) transformative quantum devices.Read moreRead less
ARC Centre of Excellence in Advanced Molecular Imaging. The Centre of Excellence in Advanced Molecular Imaging will innovatively integrate physics, chemistry and biology to unravel the complex molecular interactions that define immunity. The Centre will develop new imaging methods to visualize atomic, molecular and cellular details of how immune proteins interact and
effect immune responses. Outcomes: (i) new technological innovations leading to new imaging methods and products; and (ii) fundame ....ARC Centre of Excellence in Advanced Molecular Imaging. The Centre of Excellence in Advanced Molecular Imaging will innovatively integrate physics, chemistry and biology to unravel the complex molecular interactions that define immunity. The Centre will develop new imaging methods to visualize atomic, molecular and cellular details of how immune proteins interact and
effect immune responses. Outcomes: (i) new technological innovations leading to new imaging methods and products; and (ii) fundamental advances in understanding details of immune responses in health and disease. The Centre will enable Australia to be an international leader in biological imaging, to train next
generation interdisciplinary scientists, and to provide new insights for combating common diseases that afflict society.Read moreRead less