Discovery Early Career Researcher Award - Grant ID: DE230101371
Funder
Australian Research Council
Funding Amount
$459,592.00
Summary
Boron nitride nanosheets for low energy consumption self-cooling devices. This project aims to investigate the thermal transport mechanism of strained two-dimensional materials for self-cooling thermal management. It expects to generate new knowledge about their unique thermal properties, guiding the use of waste heat generated in electronics for self-cooling. Expected outcomes include a novel energy-effective thermal management strategy and enhanced capacity to engineer thermal transport in two ....Boron nitride nanosheets for low energy consumption self-cooling devices. This project aims to investigate the thermal transport mechanism of strained two-dimensional materials for self-cooling thermal management. It expects to generate new knowledge about their unique thermal properties, guiding the use of waste heat generated in electronics for self-cooling. Expected outcomes include a novel energy-effective thermal management strategy and enhanced capacity to engineer thermal transport in two-dimensional materials that will be deployed in miniaturised and high-density electronics to overcome overheating problems. This will provide significant benefits to the economy and the environment, such as reduced cost, energy consumption and CO2 emissions in thermal management technologies. Read moreRead less
Mid-infrared quantum dots for room temperature photodetectors and emitters. This project aims to develop new technologies for mid-wave infrared (MWIR) cameras based on quantum dots (QDs). These will include MWIR photodetectors based on QD-sensitised photodetectors and MWIR emitters based on QD electroluminescence devices.
This project expects to generate new knowledge in MWIR QDs and in devices that sense and emit infrared light.
Expected outcomes of the project include MWIR cameras that are ....Mid-infrared quantum dots for room temperature photodetectors and emitters. This project aims to develop new technologies for mid-wave infrared (MWIR) cameras based on quantum dots (QDs). These will include MWIR photodetectors based on QD-sensitised photodetectors and MWIR emitters based on QD electroluminescence devices.
This project expects to generate new knowledge in MWIR QDs and in devices that sense and emit infrared light.
Expected outcomes of the project include MWIR cameras that are smaller, lighter, lower in power consumption and cheaper than existing technologies.
This project is expected to provide significant benefits, such as dramatic reductions in the cost of infrared cameras and sensors. The high cost of infrared cameras currently limits their use in Australia largely to defence.
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Physics-based equivalent circuit models for nanoporous electrodes. This project aims to develop new physics-based equivalent circuit models for ion/electron coupled dynamics in electrified porous nanomaterials via fusing latest simulation advances with machine learning approach. This project expects to meet the challenge of high-efficient and accurate dynamic models for accelerated design, accurate diagnosis, and optimal operation of electrochemical energy storage and conversion technologies. Th ....Physics-based equivalent circuit models for nanoporous electrodes. This project aims to develop new physics-based equivalent circuit models for ion/electron coupled dynamics in electrified porous nanomaterials via fusing latest simulation advances with machine learning approach. This project expects to meet the challenge of high-efficient and accurate dynamic models for accelerated design, accurate diagnosis, and optimal operation of electrochemical energy storage and conversion technologies. The outcome will be a paradigm shift of how equivalent circuit models are developed and used, informed by new scientific knowledge and data. The proliferation of the new models will allow design and operation of more efficient and durable technologies in energy industry, benefitting Australian economy and environment.Read moreRead less
Unlocking exceptional properties through pressure-induced phase transitions. The aim of this project is to produce novel hybrid boron nitride materials by utilizing advanced green techniques of mechanochemistry and high-pressure methods to achieve a phase transition from hexagonal to wurtzite structure. The development of these materials is critical in tackling contemporary environmental and technological issues, particularly those linked to cooling systems in electronic devices and batteries. T ....Unlocking exceptional properties through pressure-induced phase transitions. The aim of this project is to produce novel hybrid boron nitride materials by utilizing advanced green techniques of mechanochemistry and high-pressure methods to achieve a phase transition from hexagonal to wurtzite structure. The development of these materials is critical in tackling contemporary environmental and technological issues, particularly those linked to cooling systems in electronic devices and batteries. The outcome of this study will be new nanomaterials with exceptional mechanical, thermal, and electronic properties, as well as new insights into mechanical-force induced green chemistry and an environmentally friendly synthesis process, and help with heat management, energy preservation, and advanced manufacturing.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100036
Funder
Australian Research Council
Funding Amount
$754,700.00
Summary
Ultra-fast structure-property characterisation of materials. The design of materials for functional and damage-tolerant applications requires detailed knowledge of their structure and the mechanisms that operate at length scales ranging from interatomic layers to micro, meso and macro scales. This project aims to establish ultra-fast processing capabilities that enable ion-damage free structural modifications and microstructure-mechanical properties characterisation across multiple length scales ....Ultra-fast structure-property characterisation of materials. The design of materials for functional and damage-tolerant applications requires detailed knowledge of their structure and the mechanisms that operate at length scales ranging from interatomic layers to micro, meso and macro scales. This project aims to establish ultra-fast processing capabilities that enable ion-damage free structural modifications and microstructure-mechanical properties characterisation across multiple length scales at unprecedented speed and accuracy. Expected outcomes include the ability to create new knowledge about multi-scale structure, composition and deformation mechanisms for the design of novel materials systems that enable manufacturing benefits throughout transportation, defence and clean energy sectors.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100019
Funder
Australian Research Council
Funding Amount
$740,000.00
Summary
National Electron Beam Irradiation Facility. This project aims to address a gap for Australian researchers and start-ups by establishing a high energy electron beam facility. This project expects to generate new knowledge and manufacturing capacity in the areas of quantum sensing and quantum computing by enriching doped diamond and other wide band gap materials via controlled electron irradiation techniques. Expected outcomes include the creation of new quantum engineered materials and devices ....National Electron Beam Irradiation Facility. This project aims to address a gap for Australian researchers and start-ups by establishing a high energy electron beam facility. This project expects to generate new knowledge and manufacturing capacity in the areas of quantum sensing and quantum computing by enriching doped diamond and other wide band gap materials via controlled electron irradiation techniques. Expected outcomes include the creation of new quantum engineered materials and devices via an academic and industry collaborative effort. The proposed facility should provide significant benefits to Australian researchers and quantum start-ups through unrestricted access to a sovereign facility entirely dedicated to their needs, aiding training of the future quantum workforce.Read moreRead less
Engineering Functional Antimicrobial Polypeptide Surfaces. Antimicrobial coatings are vital in preventing bacterial contamination but a versatile solution does not exist. Structurally nanoengineered antimicrobial peptide polymers (SNAPPs) were recently developed to fight multidrug-resistant bacteria. To expand their application into antimicrobial coatings across a range of surfaces, a simple and universal coating strategy is needed. By developing phenolic-functionalised SNAPPs, this project aims ....Engineering Functional Antimicrobial Polypeptide Surfaces. Antimicrobial coatings are vital in preventing bacterial contamination but a versatile solution does not exist. Structurally nanoengineered antimicrobial peptide polymers (SNAPPs) were recently developed to fight multidrug-resistant bacteria. To expand their application into antimicrobial coatings across a range of surfaces, a simple and universal coating strategy is needed. By developing phenolic-functionalised SNAPPs, this project aims to exploit the adhesive nature of metal–phenolic materials to rapidly coat diverse surfaces, including stainless steel and textiles. The expected outcome is the generation of antimicrobial polypeptide surfaces, which will have benefits in food safety, medical implant technology and advanced textiles.Read moreRead less
Bioinspired photoreceptor and smart neural mimicking technologies. The project aims to address fundamental questions regarding bioinspired artificial photoreceptors and neural-mimicking technologies that precisely mimic light capture abilities of photoreceptors, processing of retinal ganglion cells and functionalities in neurons. This is expected to generate new fundamental and applied knowledge in bioengineered optoelectronic systems. Expected outcomes of the project include new materials with ....Bioinspired photoreceptor and smart neural mimicking technologies. The project aims to address fundamental questions regarding bioinspired artificial photoreceptors and neural-mimicking technologies that precisely mimic light capture abilities of photoreceptors, processing of retinal ganglion cells and functionalities in neurons. This is expected to generate new fundamental and applied knowledge in bioengineered optoelectronic systems. Expected outcomes of the project include new materials with tailored properties at an atomic level for dynamic control of current under different light stimulus wavelengths. This should provide significant benefits such as new advanced materials driven smart architectures that overcome limitations of solid-state systems for next generation of smart technologies. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100138
Funder
Australian Research Council
Funding Amount
$419,804.00
Summary
Developing Switchable Ligands to Control Gold Nanocluster Interfaces. This project aims to unlock the promising catalytic activity of protected gold nanoclusters by developing switchable ligands capable of undergoing controlled detachment and exchange. This project expects to provide a detailed understanding of how the gold thiolate interface of nanoclusters influences their physical and chemical properties. Expected outcomes include the design of improved catalysts for chemical synthesis and bi ....Developing Switchable Ligands to Control Gold Nanocluster Interfaces. This project aims to unlock the promising catalytic activity of protected gold nanoclusters by developing switchable ligands capable of undergoing controlled detachment and exchange. This project expects to provide a detailed understanding of how the gold thiolate interface of nanoclusters influences their physical and chemical properties. Expected outcomes include the design of improved catalysts for chemical synthesis and biological assays using computer aided chemical modelling. These catalysts should be easier to recover after use, which should improve cost-effectiveness. They should also improve the accuracy of biological sensors, which could ultimately be used for the rapid and early detection of diseases.Read moreRead less
Design of 2D Soft Plasmonic Photocatalysts for Artificial Leaves. The project aims to fabricate 2D soft plasmonic photocatalysts with leaf-like structures and functions for solar-to chemical energy conversions. The proposed 2D photocatalysts expect to change the traditional way of designing artificial photocatalysts. Expected outcomes of this project include fabrication of 2D soft plasmonic photocatalyst with large-area, ultrathin thickness, and high flexibility, understanding their plasmon-enha ....Design of 2D Soft Plasmonic Photocatalysts for Artificial Leaves. The project aims to fabricate 2D soft plasmonic photocatalysts with leaf-like structures and functions for solar-to chemical energy conversions. The proposed 2D photocatalysts expect to change the traditional way of designing artificial photocatalysts. Expected outcomes of this project include fabrication of 2D soft plasmonic photocatalyst with large-area, ultrathin thickness, and high flexibility, understanding their plasmon-enhanced photocatalysis mechanisms, and construction of artificial leaves to perform the solar-to-chemical conversions, which can provide significant benefits, such as creating new-generation of soft energy devices and advancing Australian expertise in photochemistry, self-assembly, and functional nanomaterials.Read moreRead less