Discovery Early Career Researcher Award - Grant ID: DE170100362
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Nanostructured metal hydrides for practical hydrogen storage applications. This project aims to synthesise nanostructured metal hydrides with particle size smaller than 5 nm. The practical applications of metal hydrides as advanced solid-state hydrogen storage materials require substantial knowledge and delicate engineering of materials on the nanoscale. Combined with controllable modification on the nanoscale, the optimised metal hydrides will enhance the performance of hydrogen storage materia ....Nanostructured metal hydrides for practical hydrogen storage applications. This project aims to synthesise nanostructured metal hydrides with particle size smaller than 5 nm. The practical applications of metal hydrides as advanced solid-state hydrogen storage materials require substantial knowledge and delicate engineering of materials on the nanoscale. Combined with controllable modification on the nanoscale, the optimised metal hydrides will enhance the performance of hydrogen storage materials. This project is expected to advance understanding of the technologies of metal hydrides as hydrogen storage materials and develop practical applications of metal hydrides in storage tanks for fuel cells. Hydrogen energy could also reduce carbon dioxide emissions and alleviate air pollution.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100504
Funder
Australian Research Council
Funding Amount
$384,000.00
Summary
Interphases and interfaces of nanomaterials in potassium-ion batteries. This project aims to improve the fundamental understanding of interfacial interactions in multicomponent materials, which is a critical precursor to successfully designing and experimentally validating novel layered sulphide systems for potassium-ion batteries. A new layered structure construction technique will be employed to enhance the intrinsic electronic and ionic conductivities in the anode by controllable interphase a ....Interphases and interfaces of nanomaterials in potassium-ion batteries. This project aims to improve the fundamental understanding of interfacial interactions in multicomponent materials, which is a critical precursor to successfully designing and experimentally validating novel layered sulphide systems for potassium-ion batteries. A new layered structure construction technique will be employed to enhance the intrinsic electronic and ionic conductivities in the anode by controllable interphase and interface engineering. The expected outcomes of this project are to generate potassiumion batteries with high energy density, high safety, and long cycle life for next generation energy storage. This project should give Australia a competitive edge in the globally emerging sustainable manufacturing and energy-storage technologies.Read moreRead less
High Energy Density - High Delivery Rate Thermal Energy Storage. This project aims to address the intermittency of renewable energy sources using novel thermal storage media. Advanced heat transfer modelling and in situ neutron diffraction and imaging are intended to be used to optimise the microstructure of newly developed miscibility gap thermal storage systems. The new media store energy as the latent heat of fusion of one phase in a stable, high thermal conductivity inverted microstructure. ....High Energy Density - High Delivery Rate Thermal Energy Storage. This project aims to address the intermittency of renewable energy sources using novel thermal storage media. Advanced heat transfer modelling and in situ neutron diffraction and imaging are intended to be used to optimise the microstructure of newly developed miscibility gap thermal storage systems. The new media store energy as the latent heat of fusion of one phase in a stable, high thermal conductivity inverted microstructure. The high energy density of the latent heat (0.5-4.5 Mega Joules/Litre) requires storage volumes as little as five per cent of those relying upon heat capacity and the metal matrix has a hundred-fold greater thermal conductivity than current systems. It is proposed that a range of such materials will be engineered for concentrated solar thermal and space heating applications.Read moreRead less
Redox-sensitised dense graphene to boost compact supercapacitors. This project will create redox-sensitised ion-accessible dense graphene to improve the energy density of supercapacitors (SCs). The energy density of SCs is a bottle neck for long-lasting power supply to vehicles, small devices and mobile electronics. By incorporating a redox coordination framework in shrunk graphene to increase the charge storage capacity and speed up the charge movement and further incorporating ionic liquids in ....Redox-sensitised dense graphene to boost compact supercapacitors. This project will create redox-sensitised ion-accessible dense graphene to improve the energy density of supercapacitors (SCs). The energy density of SCs is a bottle neck for long-lasting power supply to vehicles, small devices and mobile electronics. By incorporating a redox coordination framework in shrunk graphene to increase the charge storage capacity and speed up the charge movement and further incorporating ionic liquids in the tailored electrodes, the project will produce SC’s with higher operating voltage and longer cycle life. Such SCs will possess dramatically high energy density, without compromising the power density. This project will improve the efficiency of modern electronics through the development of the next generation of SCs.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100427
Funder
Australian Research Council
Funding Amount
$446,000.00
Summary
Engineered multifunctional membranes for aqueous organic redox flow battery. This project aims to develop multifunctional membranes with high ion conductivity and selectivity and high energy density to address the key challenges in the development of aqueous organic redox flow battery for renewable energy storage. The project will develop novel methodologies for precisely tuning and functionalising microporous materials to achieve cost-effective and scalable fabrication of membranes with multi-f ....Engineered multifunctional membranes for aqueous organic redox flow battery. This project aims to develop multifunctional membranes with high ion conductivity and selectivity and high energy density to address the key challenges in the development of aqueous organic redox flow battery for renewable energy storage. The project will develop novel methodologies for precisely tuning and functionalising microporous materials to achieve cost-effective and scalable fabrication of membranes with multi-functions, thus improving the energy efficiency and retaining the cycling capacity of redox flow batteries. The advancement of multifunctional membranes will enhance the efficiency of storage of intermittent and fluctuating renewable resources, thereby contributing to the reduction of carbon footprint in Australia. Read moreRead less
Multifunctional trilayer separator for durable multivalent energy storage. This project aims to develop an important new family of economical, high energy, multivalent batteries based on an abundant element, sulphur. The project plans to design a new battery separator to enable long-term stability in sulphur-based rechargeable batteries. This type of separator is of critical importance in many membrane-involved energy storage technologies. The project plans to use leading-edge durable energy tec ....Multifunctional trilayer separator for durable multivalent energy storage. This project aims to develop an important new family of economical, high energy, multivalent batteries based on an abundant element, sulphur. The project plans to design a new battery separator to enable long-term stability in sulphur-based rechargeable batteries. This type of separator is of critical importance in many membrane-involved energy storage technologies. The project plans to use leading-edge durable energy technologies to strengthen the development of residential energy systems and the involvement of renewable energy sources in modern grid.Read moreRead less
New hierarchical electrode design for high-power lithium ion batteries. This project aims to develop new types of hierarchical electrodes for high-rate lithium ion batteries with long cycling life. The key concepts are the development of multi-shelled hollow structured silicon-based anode and Li-rich layered oxides cathode to achieve both high power and energy density, and the adoption of graphene to further improve rate capability and cycling stability. Effective energy storage systems play an ....New hierarchical electrode design for high-power lithium ion batteries. This project aims to develop new types of hierarchical electrodes for high-rate lithium ion batteries with long cycling life. The key concepts are the development of multi-shelled hollow structured silicon-based anode and Li-rich layered oxides cathode to achieve both high power and energy density, and the adoption of graphene to further improve rate capability and cycling stability. Effective energy storage systems play an important role in the development of renewable energies and electric vehicles. The project outcomes will lead to innovative technologies in low carbon emission transportation and efficient energy storage systems.Read moreRead less
Nanoporous nanorods with improved electrochemical properties. This project applies the latest nanotechnology to produce new nanomaterials for energy storage applications. The aim is to significantly improve supercapacitor performance for use in the storage of clean energy and harvesting of wasted energy which will contribute to a clean energy economy.
A new design strategy for supercapacitors. This project aims to build a new equivalent electric circuit model using structurally tuneable graphene-based porous electrodes to establish a quantitative structure-property-performance relationship for super-capacitors. The new model will then be used to design novel electrode and device architectures to realise new energy storage devices with high usable storage capacity at high operation rates. This new computer-aided strategy will greatly accelerat ....A new design strategy for supercapacitors. This project aims to build a new equivalent electric circuit model using structurally tuneable graphene-based porous electrodes to establish a quantitative structure-property-performance relationship for super-capacitors. The new model will then be used to design novel electrode and device architectures to realise new energy storage devices with high usable storage capacity at high operation rates. This new computer-aided strategy will greatly accelerate the design of next-generation high-performance super-capacitors, and bring significant benefit to Australia's emerging knowledge-based manufacturing industry.Read moreRead less
Improved models of nanoporous carbons for greater fundamental insight and better sustainable technology. Storage of hydrogen and energy from intermittent sources like solar and wind, and 'carbon capture' from coal-fired power stations are essential requirements for a sustainable future. A state-of-the-art computer model will be developed and demonstrated to help deliver these and other technologies for a safe and sustainable future.