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Discovery Early Career Researcher Award - Grant ID: DE240100627
Funder
Australian Research Council
Funding Amount
$436,250.00
Summary
Topological phonons in solids. This project aims to create a complete list of possible topological phonons in time-reversal-invariant systems via symmetry analysis, to determine ideal topological phononic materials, and to study topological phonon-related properties and possible applications. The significant outcomes of this project will be the generation of new knowledge that will help conclude the search for novel topological phonons and the prediction of novel topological phononic materials b ....Topological phonons in solids. This project aims to create a complete list of possible topological phonons in time-reversal-invariant systems via symmetry analysis, to determine ideal topological phononic materials, and to study topological phonon-related properties and possible applications. The significant outcomes of this project will be the generation of new knowledge that will help conclude the search for novel topological phonons and the prediction of novel topological phononic materials based on the complete classification list of topological phonons. The outcomes of this project should unlock the physics of the exotic topological phonons and lay a solid foundation for applying topological phononic materials based on their unprecedented properties.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101567
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Adding value to wastewater treatment - ultrasound enhanced crystallisation. The difficulty of disposing of concentrated liquid wastes is forcing industries to reassess their waste treatment processes and strive for zero liquid discharge. This project will add value to industrial waste by improving extraction of purified water and valuable solutes from such concentrates by combining ultrasound with crystallisation processes.
Discovery Early Career Researcher Award - Grant ID: DE150101499
Funder
Australian Research Council
Funding Amount
$355,801.00
Summary
First-principles design and characterisation of topological materials. It has long been predicted that materials may contain special topological order. The recent discovery of topological insulators reveals the tip of the iceberg, but many theoretical hypotheses, such as the existence of the fractional Chern insulator and quantum spin liquid, remain elusive. This project aims to bridge the gap between conceptual models and real materials by using first-principles calculations. The plan is to ide ....First-principles design and characterisation of topological materials. It has long been predicted that materials may contain special topological order. The recent discovery of topological insulators reveals the tip of the iceberg, but many theoretical hypotheses, such as the existence of the fractional Chern insulator and quantum spin liquid, remain elusive. This project aims to bridge the gap between conceptual models and real materials by using first-principles calculations. The plan is to identify and engineer topological electronic bands in experimentally feasible materials, characterise existing quantum frustrated materials and connect these materials with minimal theoretical models. This project also aims to reveal further families of topological materials and clarify their physical properties.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
Discovery Early Career Researcher Award - Grant ID: DE160100167
Funder
Australian Research Council
Funding Amount
$373,536.00
Summary
Electro-optical quantum transport in semiconductor microcavities. The project seeks to expand fundamental knowledge in the new area of exciton-polariton physics which has a range of practical applications. This project plans to connect fundamental study in quantum physics with application-oriented research involving elements of quantum engineering. The project plans to investigate the transport of exciton polaritons – hybrid light–matter particles that can propagate nearly as fast as light and a ....Electro-optical quantum transport in semiconductor microcavities. The project seeks to expand fundamental knowledge in the new area of exciton-polariton physics which has a range of practical applications. This project plans to connect fundamental study in quantum physics with application-oriented research involving elements of quantum engineering. The project plans to investigate the transport of exciton polaritons – hybrid light–matter particles that can propagate nearly as fast as light and are very robust. It may allow us to better understand fundamental features in physics and optics, and to model and construct optoelectronic devices such as quantum switchers, filters, transistors and detectors. The theory that the project aims to develop could be employed in different spheres of modern physics, chemistry, and medicine and biology.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240101283
Funder
Australian Research Council
Funding Amount
$361,000.00
Summary
Linking Australia’s basement and cover mineral systems . The aim of this research is to use revolutionary new mineral-dating techniques to test the hypothesis that low-temperature fluids can transport metals from Australia's richly endowed geological basement to form new mineral deposits in the sedimentary basins that cover most of the continent. Sedimentary-hosted mineral systems are the largest source of the critical metal cobalt and the second largest source of copper on Earth. These two meta ....Linking Australia’s basement and cover mineral systems . The aim of this research is to use revolutionary new mineral-dating techniques to test the hypothesis that low-temperature fluids can transport metals from Australia's richly endowed geological basement to form new mineral deposits in the sedimentary basins that cover most of the continent. Sedimentary-hosted mineral systems are the largest source of the critical metal cobalt and the second largest source of copper on Earth. These two metals are essential to developing the green energy infrastructure and technologies that underpin a net zero economy. The expected outcomes are a detailed record of paleo-fluid flow and metal cycling in Australia's highly prospective sedimentary basins. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101662
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Non-Oxidative and Scalable Electrochemical Production of Functional Graphene and its Nanohybrids. The lack of cost-effective and scalable graphene production methods is the current bottleneck that impedes the commercialisation of advanced graphene-based nanomaterials. Novel electrochemical production of those functional materials directly from bulk graphite not only holds the key to the solution but also provides a non-oxidative route for the production of highly conductive graphene which is wel ....Non-Oxidative and Scalable Electrochemical Production of Functional Graphene and its Nanohybrids. The lack of cost-effective and scalable graphene production methods is the current bottleneck that impedes the commercialisation of advanced graphene-based nanomaterials. Novel electrochemical production of those functional materials directly from bulk graphite not only holds the key to the solution but also provides a non-oxidative route for the production of highly conductive graphene which is well suited for applications such as biosensing, energy storage and conversion. Besides achieving scientific breakthroughs in graphene electrochemistry, this project will directly benefit many Australian socio-economic objectives, including manufacturing of Australia's natural resources into valuable energy related products.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150100326
Funder
Australian Research Council
Funding Amount
$338,266.00
Summary
The role of subduction initiation in the evolution of Earth’s oceans. An outstanding question in plate tectonics is how do oceans start to close? The Wilson Cycle describes the life of an ocean in three phases: opening and spreading, foundering of its passive margins and development of new subduction zones, and consumption and closure. It has been suggested that new subduction zones are difficult to form and thereby they are more likely to spread from ocean to ocean like a sort of invasive mecha ....The role of subduction initiation in the evolution of Earth’s oceans. An outstanding question in plate tectonics is how do oceans start to close? The Wilson Cycle describes the life of an ocean in three phases: opening and spreading, foundering of its passive margins and development of new subduction zones, and consumption and closure. It has been suggested that new subduction zones are difficult to form and thereby they are more likely to spread from ocean to ocean like a sort of invasive mechanism. This project aims to make use of laboratory models and plate kinematic modelling to understand how subduction zones are initiating and propagating in the Atlantic. The project aims to provide clues on how ancient oceans may have closed and whether the Atlantic is already in its turning point.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100987
Funder
Australian Research Council
Funding Amount
$306,186.00
Summary
Designing next generation smart materials for capturing toxic gases. The project aims to use rapid computational and experimental screening tools to speed the design and development of robust metal organic frameworks for detecting and capturing toxic gases. Detecting and capturing toxic gases is vital for numerous industrial processes. Metal organic frameworks are porous materials that hold the world record for specific surface area and storage of gases. Their development and application in prac ....Designing next generation smart materials for capturing toxic gases. The project aims to use rapid computational and experimental screening tools to speed the design and development of robust metal organic frameworks for detecting and capturing toxic gases. Detecting and capturing toxic gases is vital for numerous industrial processes. Metal organic frameworks are porous materials that hold the world record for specific surface area and storage of gases. Their development and application in practical conditions require stability in the operating environment. It is expected that this project will lead to the development of efficient and effective porous materials that detect and capture toxic gases, thus improving Australian industry’s ability to monitor and eliminate emissions, improving air quality and public health.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