Developing lithium metal batteries – a game-changer for renewable energy. This project aims to develop nanostructured lithium metal anodes for rechargeable lithium metal batteries with high energy density and excellent cycle life. Lithium metal batteries such as lithium-sulfur batteries and lithium carbon-dioxide batteries present great opportunities for long-range electric vehicles and high-efficient renewable energy storage. Through the rational structure design and advanced interface engineer ....Developing lithium metal batteries – a game-changer for renewable energy. This project aims to develop nanostructured lithium metal anodes for rechargeable lithium metal batteries with high energy density and excellent cycle life. Lithium metal batteries such as lithium-sulfur batteries and lithium carbon-dioxide batteries present great opportunities for long-range electric vehicles and high-efficient renewable energy storage. Through the rational structure design and advanced interface engineering, the developed lithium metal anodes are expected to overcome the critical issues that hindered their practical application for high-energy batteries. The success of this project will provide new technological solutions for next-generation energy storage devices.Read moreRead less
Engineering vanadium oxide-based cathode for aqueous ammonium ion batteries. This project aims to develop the next-generation rechargeable aqueous ammonium ion batteries and the scaled-up prototypes. It will be innovatively powered by nonmetallic charge carriers to show superior safety, low cost, high rate and cycle performance, and large capacity, ensuring realistic implementation for industrial purposes. Expected outcomes include a series of chemically and morphologically tuned vanadium oxide- ....Engineering vanadium oxide-based cathode for aqueous ammonium ion batteries. This project aims to develop the next-generation rechargeable aqueous ammonium ion batteries and the scaled-up prototypes. It will be innovatively powered by nonmetallic charge carriers to show superior safety, low cost, high rate and cycle performance, and large capacity, ensuring realistic implementation for industrial purposes. Expected outcomes include a series of chemically and morphologically tuned vanadium oxide-based cathode materials, a novel and reliable working principle based on reversible ammonium ion storage, and battery pack prototypes targeting industry demanded energy density and lifespan. Via industrial pilot trials, commercial benefits will be fast tracked for clean energy storage, net zero future and industry upgrades.Read moreRead less
2D vertical heterostructures for multi-functional energy applications. This project aims to develop multi-functional 2D vertical heterostructures for sustainable energy applications. A key challenge in fabricating 2D vertical heterostructures is the re-stacking of layered materials. This project will utilize edge-rich vertical graphene to unleash the full potential of 2D vertical heterostructures by combining the advantages of individual building blocks while mitigating the associated shortcomin ....2D vertical heterostructures for multi-functional energy applications. This project aims to develop multi-functional 2D vertical heterostructures for sustainable energy applications. A key challenge in fabricating 2D vertical heterostructures is the re-stacking of layered materials. This project will utilize edge-rich vertical graphene to unleash the full potential of 2D vertical heterostructures by combining the advantages of individual building blocks while mitigating the associated shortcomings. Expected outcomes will include improved electrochemical performance of materials and an integrated energy system utilizing these multi-functional materials to produce green hydrogen at low cost and high efficiency. The project should contribute largely to Australia’s transition to robust and affordable clean energy.Read moreRead less
Asymmetric Biomembranes for Blue Energy Harvesting. This project aims to develop a new class of biomembranes for efficient ion-selective transport, to address the challenge of low power density facing the realisation of blue energy harvesting. This will be achieved using innovative chemistries guided by theoretical modelling to endow membranes with unique features: heterogeneities in surface charge and pore structure. Expected outcomes include a new concept for membrane design, advancement of kn ....Asymmetric Biomembranes for Blue Energy Harvesting. This project aims to develop a new class of biomembranes for efficient ion-selective transport, to address the challenge of low power density facing the realisation of blue energy harvesting. This will be achieved using innovative chemistries guided by theoretical modelling to endow membranes with unique features: heterogeneities in surface charge and pore structure. Expected outcomes include a new concept for membrane design, advancement of knowledge in energy conversion, creation of a new prototype power device without need of any external forces, and significant advances in self-powered wearable electronics potentially revolutionizing industries such as healthcare and entertainment. Read moreRead less
Hybrid Toughening of Carbon Fibre Composites for Liquid Hydrogen Storage. This project aims to develop hybrid toughening technologies to overcome the major problem of transverse matrix cracking and splitting in existing carbon fibre composites when subjected to thermal-mechanical loading at the ultracold liquid hydrogen temperature. Nano-toughened thin-ply carbon fibre layers will be hybridised with standard-ply laminates to sustain internal pressure and external impact loading at cryogenic temp ....Hybrid Toughening of Carbon Fibre Composites for Liquid Hydrogen Storage. This project aims to develop hybrid toughening technologies to overcome the major problem of transverse matrix cracking and splitting in existing carbon fibre composites when subjected to thermal-mechanical loading at the ultracold liquid hydrogen temperature. Nano-toughened thin-ply carbon fibre layers will be hybridised with standard-ply laminates to sustain internal pressure and external impact loading at cryogenic temperatures without leaks. The hybrid composites are expected to enable Australian companies to engineer, manufacture and export lightweight carbon fibre tanks for storing and exporting liquid hydrogen, which is emerging as a transformational opportunity for Australia to become a global supplier of green energy.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100049
Funder
Australian Research Council
Funding Amount
$1,200,000.00
Summary
In-situ nanomechanical testing for materials under extreme environments. This project aims to establish a state-of-the-art in-situ nanomechanical testing capability for materials under extreme environments. A cutting-edge nanoindentation stage with customisable modules, as well as an optimally configured scanning electron microscope, will enable this capability for the first time in Australia. The expected outcomes will provide valuable insights into how microstructures affect mechanical propert ....In-situ nanomechanical testing for materials under extreme environments. This project aims to establish a state-of-the-art in-situ nanomechanical testing capability for materials under extreme environments. A cutting-edge nanoindentation stage with customisable modules, as well as an optimally configured scanning electron microscope, will enable this capability for the first time in Australia. The expected outcomes will provide valuable insights into how microstructures affect mechanical properties at temperatures ranging from -150 to 1000 °C, strain rates from 10E-5/s to 10E5/s, and liquid environments. The resulting knowledge will guide the development of structural materials that withstand harsh environmental conditions, thereby advancing Australia's advanced manufacturing and sustainable energy sectors.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100021
Funder
Australian Research Council
Funding Amount
$440,154.00
Summary
Kesterite/Si Tandem Structure for Unassisted Overall Solar Fuel Production. This project aims to develop Kesterite/Si tandem device for photoelectrochemical carbon dioxide reduction to produce solar fuels. It is expected to reveal the photoelectrochemical mechanism of the p-n heterojunction, thereby promoting solar energy utilisation and greenhouse gas reduction. Expected outcomes include delivery of a high-performance kesterite photocathode for efficient CO2 reduction, a kesterite/Si tandem dev ....Kesterite/Si Tandem Structure for Unassisted Overall Solar Fuel Production. This project aims to develop Kesterite/Si tandem device for photoelectrochemical carbon dioxide reduction to produce solar fuels. It is expected to reveal the photoelectrochemical mechanism of the p-n heterojunction, thereby promoting solar energy utilisation and greenhouse gas reduction. Expected outcomes include delivery of a high-performance kesterite photocathode for efficient CO2 reduction, a kesterite/Si tandem device for overall unassisted solar fuel production, and an in-depth understanding of structure-performance correlation to guide future heterojunction photocathode design. This project should provide significant benefits in minimising fossil fuel consumption, increasing energy security, and expanding the clean energy industry.Read moreRead less
Mid-Career Industry Fellowships - Grant ID: IM230100125
Funder
Australian Research Council
Funding Amount
$1,053,296.00
Summary
Life prediction and optimisation of advanced first-wall fusion materials. The project focusses on accelerating the development radiation-tolerant materials for fusion energy, in collaboration with HB11 and Tokamak Energy. Specifically, we aim to understand the degradation mechanisms of the “first-wall” component, which is exposed to high energy radiation. In turn, this will (a) enable accurate life assessments of the component, and (b) inform how to optimise it material for longer-lasting fusion ....Life prediction and optimisation of advanced first-wall fusion materials. The project focusses on accelerating the development radiation-tolerant materials for fusion energy, in collaboration with HB11 and Tokamak Energy. Specifically, we aim to understand the degradation mechanisms of the “first-wall” component, which is exposed to high energy radiation. In turn, this will (a) enable accurate life assessments of the component, and (b) inform how to optimise it material for longer-lasting fusion devices. The outcomes directly reduce the cost of energy produced by the partner’s fusion devices, help bridge the gap from TRL 3 to 6, and provide valuable inputs for techno-economic models and licensing applications. The fellowship will also enhance Australia’s prominence in the international fusion energy stage.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100497
Funder
Australian Research Council
Funding Amount
$413,847.00
Summary
In-situ Imaging and Detecting Electron Transfer for Single Site Reaction. This research aims to investigate and detect electron transfer numbers in oxygen reduction under atomic scale at one single active site through in-situ Electrochemical Scanning Tunneling Microscopy (ECSTM). Innovations are expected in the novel detection concept, novel nanofabrication approach and innovative ECSTM tip-based imaging and detection technique. Expected outcomes of the project include a reliable detection techn ....In-situ Imaging and Detecting Electron Transfer for Single Site Reaction. This research aims to investigate and detect electron transfer numbers in oxygen reduction under atomic scale at one single active site through in-situ Electrochemical Scanning Tunneling Microscopy (ECSTM). Innovations are expected in the novel detection concept, novel nanofabrication approach and innovative ECSTM tip-based imaging and detection technique. Expected outcomes of the project include a reliable detection technique for electron transfer detection and precisely synthesized catalysts for certain applications. This fundamental groundwork provides the guidance to design and develop a high-efficiency electrocatalyst to facilitate green energy storage technology and accelerate Australia's transition into a sustainable economy.Read moreRead less
Tandem Photocatalytic Conversion of CO2 to High Value Hydrocarbon Products. Converting carbon dioxide (CO2) into hydrocarbon products is ideal for combating anthropogenic emissions whilst reducing our reliance on fossil fuels. Despite the significant advantages, CO2 valorisation is hindered by barriers such as high energy requirements and low-value products (methane and carbon monoxide). This project will establish a sustainable approach to CO2 valorisation using a unique tandem solar-driven hie ....Tandem Photocatalytic Conversion of CO2 to High Value Hydrocarbon Products. Converting carbon dioxide (CO2) into hydrocarbon products is ideal for combating anthropogenic emissions whilst reducing our reliance on fossil fuels. Despite the significant advantages, CO2 valorisation is hindered by barriers such as high energy requirements and low-value products (methane and carbon monoxide). This project will establish a sustainable approach to CO2 valorisation using a unique tandem solar-driven hierarchical catalyst array to offset energy requirements and directly yield high-value hydrocarbon products, such as ethane (C2H6) and ethanol (CH3CH2OH), from captured CO2.Read moreRead less