Sodium ion interactions with biomass-derived hard carbon electrodes. This project aims to investigate sodium ion behavior when electrochemically interacting with hard carbon electrode materials by using both in-situ and ex-situ techniques in combination with advanced computational methods. This project expects to generate new knowledge and establish structure-property-performance correlations, thus providing guidelines and strategies for synthesising cost-effective electrode materials from bioma ....Sodium ion interactions with biomass-derived hard carbon electrodes. This project aims to investigate sodium ion behavior when electrochemically interacting with hard carbon electrode materials by using both in-situ and ex-situ techniques in combination with advanced computational methods. This project expects to generate new knowledge and establish structure-property-performance correlations, thus providing guidelines and strategies for synthesising cost-effective electrode materials from biomass for developing sustainable sodium-ion batteries. The intended outcome of this project includes knowledge advancement, enhanced capability to build international collaborations, training of early career researchers and students, and positioning Australia on the world map as a world-leading nation in energy storage.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220101577
Funder
Australian Research Council
Funding Amount
$446,639.00
Summary
Two-Dimensional Covalent Organic Framework for Next-Generation Batteries. This project aims to develop advanced two-dimensional (2D) covalent organic framework (COF) materials for sodium and potassium-ion batteries. It expects to generate a new family of few-layered 2D COF materials and their 2D-2D heterostructured composites with improved electrochemical properties, and develop processing technologies and fundamental understanding of COF-based electrodes for flexible sodium and potassium-ion ba ....Two-Dimensional Covalent Organic Framework for Next-Generation Batteries. This project aims to develop advanced two-dimensional (2D) covalent organic framework (COF) materials for sodium and potassium-ion batteries. It expects to generate a new family of few-layered 2D COF materials and their 2D-2D heterostructured composites with improved electrochemical properties, and develop processing technologies and fundamental understanding of COF-based electrodes for flexible sodium and potassium-ion batteries. Expected outcomes include novel materials, technologies, and energy-storage options for Australia. Significant economic and environmental benefits are expected from developing advanced sodium and potassium-ion batteries with low cost, high energy density, and improved safety for renewable energy storage.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL170100101
Funder
Australian Research Council
Funding Amount
$2,843,970.00
Summary
Towards sustainable electrochemical energy storage technology. This project aims to address fundamental issues on electrochemical energy storage technology using sodium-ion capacitors, by designing novel electrode materials and utilising advanced, in-situ and ex-situ instrumental techniques in combination with modern computational simulation methods. The project will lead to a complete understanding of the charge storage mechanism and transport kinetics in sodium-ion capacitors, providing guide ....Towards sustainable electrochemical energy storage technology. This project aims to address fundamental issues on electrochemical energy storage technology using sodium-ion capacitors, by designing novel electrode materials and utilising advanced, in-situ and ex-situ instrumental techniques in combination with modern computational simulation methods. The project will lead to a complete understanding of the charge storage mechanism and transport kinetics in sodium-ion capacitors, providing guidelines for developing sustainable electrochemical energy storage technology. The project expects to generate new knowledge in energy storage including capacity building, training of young scientists, and intellectual property with potential commercialised products.Read moreRead less
Low cost solution-processable 2D nanomaterials for smart windows. This project aims to develop low cost and scalable synthesis of the active functional nanomaterials in smart windows, their facile application techniques, and their integration into the glass manufacturing process. Smart windows, with thermochromic and electrochromic functionalities, will play important roles towards efficient energy usage and conservation (in terms of air-conditioning and lighting) in most buildings including off ....Low cost solution-processable 2D nanomaterials for smart windows. This project aims to develop low cost and scalable synthesis of the active functional nanomaterials in smart windows, their facile application techniques, and their integration into the glass manufacturing process. Smart windows, with thermochromic and electrochromic functionalities, will play important roles towards efficient energy usage and conservation (in terms of air-conditioning and lighting) in most buildings including offices, schools, and residential homes. . The intended outcome of this project is to facilitate the commercialisation of low-cost, energy-saving smart windows for efficient energy usage and conservation, which is an integral part of a sustainable environment.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101212
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
In-situ Atomic-scale Deformation Mechanism of ultrafine Nanocrystalline Pt. Understanding the deformation of nanocrystalline (NC) metals is crucial for their practical application. So far, the deformation mechanism of ultrafine NC metals with grain size below 15 nanometre has been predicted by simulations which need to be verified experimentally. Using different in situ transmission electron microscopy deformation approaches, this project aims to determine deformation mechanisms of ultrafine NC ....In-situ Atomic-scale Deformation Mechanism of ultrafine Nanocrystalline Pt. Understanding the deformation of nanocrystalline (NC) metals is crucial for their practical application. So far, the deformation mechanism of ultrafine NC metals with grain size below 15 nanometre has been predicted by simulations which need to be verified experimentally. Using different in situ transmission electron microscopy deformation approaches, this project aims to determine deformation mechanisms of ultrafine NC platinum (Pt) at atomic-scale and to clarify how the deformation behaviour affects mechanical properties. The expected outcomes will advance the knowledge base in ultrafine NC metals and will provide guidance for developing advanced metallic materials with high strength/ductility that are the backbone for developing flexible and bendable devices.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100026
Funder
Australian Research Council
Funding Amount
$480,000.00
Summary
A surface characterisation facility. This surface characterisation facility will provide scientists with an understanding of material's surfaces and interfaces. This will lead to a range of new technologies and innovative solutions required to address the many resource and environmental challenges facing our planet now and in the future.
Australian Laureate Fellowships - Grant ID: FL160100089
Funder
Australian Research Council
Funding Amount
$2,600,796.00
Summary
In situ electron microscopy toward new materials and applications. In situ electron microscopy toward new materials and applications. This project aims to develop materials for structural and green energy applications, using spatially-resolved, dynamic in situ transmission electron microscopy to research fundamental mechanical, electrical, thermal, optical, optoelectronic and photovoltaic properties of diverse nanostructures. These techniques measure nanomaterial (one-dimensional nanotubes and n ....In situ electron microscopy toward new materials and applications. In situ electron microscopy toward new materials and applications. This project aims to develop materials for structural and green energy applications, using spatially-resolved, dynamic in situ transmission electron microscopy to research fundamental mechanical, electrical, thermal, optical, optoelectronic and photovoltaic properties of diverse nanostructures. These techniques measure nanomaterial (one-dimensional nanotubes and nanowires and two-dimensional graphene-like nanosheets) response to external stimuli, including mechanical, electrical, optical and thermal stimuli. Anticipated outcomes are new ultralight and superstrong structural composites and ‘green-energy’ nanomaterials, such as solar cells, touch panels, batteries, supercapacitors, field-effect transistors, light sensors and displays.Read moreRead less
Solar-driven thermochemical dissociation of carbon dioxide and water to produce carbon-neutral fuels. The biggest challenge to humanity of the century is to develop enabling clean energy resources to encounter rapidly diminished fossil fuel and accelerated global warming conditions. This project will offer a solution by developing a unique solar-driven thermochemical system capable of cleaving carbon dioxide and water to produce artificial syngas.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100042
Funder
Australian Research Council
Funding Amount
$970,000.00
Summary
Cryo-Focused Ion Beam Facility for soft and hard materials. The multipurpose Cryo-Focused Ion beam scanning electron microscope (Cryo-FIB) Facility aims to provide revolutionary insights into beam sensitive materials and biological molecules at high magnification. This instrument will be a unique configuration and the most advanced of its kind in Australia. It will be fitted with a gallium ion source, cryo-stage, cryo-lift out and cryo-transfer suite and capable of imaging and compositional anal ....Cryo-Focused Ion Beam Facility for soft and hard materials. The multipurpose Cryo-Focused Ion beam scanning electron microscope (Cryo-FIB) Facility aims to provide revolutionary insights into beam sensitive materials and biological molecules at high magnification. This instrument will be a unique configuration and the most advanced of its kind in Australia. It will be fitted with a gallium ion source, cryo-stage, cryo-lift out and cryo-transfer suite and capable of imaging and compositional analysis in two- and three-dimensions and preparing samples for atomic-scale analyses with complementary cryo-microscopies. This equipment aims to facilitate innovative research in the fields of energy materials, advanced manufacturing, nanomaterials and in situ cell and structural biology.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100036
Funder
Australian Research Council
Funding Amount
$440,000.00
Summary
National in-situ transmission electron microscope facilities. This project will establish six complementary transmission electron microscope (TEM) facilities at various locations. The establishment of the facilities will be a key step in developing advanced capacity in Australia and will support ground-breaking research in diverse material systems for various high-performing applications, including electronics, optoelectronics, light metals, biomaterials, energy, and environment.