Discovery Early Career Researcher Award - Grant ID: DE120102784
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Water-swellable rubber with nanoparticle-enabled super capacity as smart water-leakage sealant. A novel water-swellable rubber (WSR) sealant with continuous hydrophobic phase and isolated hydrophilic phase is developed for stopping water leakage from gaps and cracks. Nanoparticle-enabled blocks and network channels in rubber matrix effectively improve the integrity and capability of WSR as smart water-leakage sealants in various applications.
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
Extremely lightweight and superelastic cellular materials. This project aims to synthesise a new generation of extremely lightweight, superelastic yet mechanically robust graphene-based cellular materials, develop new strategies to strengthen and functionalise them with other functional polymers or nanoparticles, and explore new techniques to characterise their unique mechanical, electrical and thermal properties for a range of potential applications. The new knowledge obtained would significant ....Extremely lightweight and superelastic cellular materials. This project aims to synthesise a new generation of extremely lightweight, superelastic yet mechanically robust graphene-based cellular materials, develop new strategies to strengthen and functionalise them with other functional polymers or nanoparticles, and explore new techniques to characterise their unique mechanical, electrical and thermal properties for a range of potential applications. The new knowledge obtained would significantly advance our understanding of extremely lightweight and multifunctional cellular materials as well as graphene-based bulk materials. Project outcomes are expected to help generate high value-added technological applications from natural graphite.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100036
Funder
Australian Research Council
Funding Amount
$359,446.00
Summary
Rechargeable room-temperature sodium-oxygen batteries. This project aims to develop high performance room-temperature sodium-oxygen batteries as a green and low-cost power source for large scale electrical energy storage. Through electrode architecture design, this research intends to significantly improve the performance of sodium-oxygen batteries, including specific capacity, cycle life and round-trip energy efficiency. Expected outcomes include reducing consumption of fossil fuels to generate ....Rechargeable room-temperature sodium-oxygen batteries. This project aims to develop high performance room-temperature sodium-oxygen batteries as a green and low-cost power source for large scale electrical energy storage. Through electrode architecture design, this research intends to significantly improve the performance of sodium-oxygen batteries, including specific capacity, cycle life and round-trip energy efficiency. Expected outcomes include reducing consumption of fossil fuels to generate electricity, with benefits for the environment, climate change and energy security.Read moreRead less
Engineering the Microstructure of Electrodes for Advanced Fuel Cells. A polymer solution-based integration technique is proposed to be developed to fabricate polymer electrolyte membrane fuel cells, allowing for effective engineering of the porous networks and interfaces within electrodes and cells. This novel systems materials engineering approach is expected to overcome the drawbacks of the conventional hot pressing method, enabling precise integration of nanostructured electrodes and membrane ....Engineering the Microstructure of Electrodes for Advanced Fuel Cells. A polymer solution-based integration technique is proposed to be developed to fabricate polymer electrolyte membrane fuel cells, allowing for effective engineering of the porous networks and interfaces within electrodes and cells. This novel systems materials engineering approach is expected to overcome the drawbacks of the conventional hot pressing method, enabling precise integration of nanostructured electrodes and membrane into high-performance, flexible fuel cells. The outcomes of this research aim to provide a unique opportunity for Australia to become a world leader in the rapidly-emerging clean energy technology, and critical manufacturing of new energy generation systems for domestic uses and exports, thereby producing important economic benefits.Read moreRead less
New high energy density cathode materials for lithium ion batteries. This project aims to develop new high-energy-density and low-cost lithium-rich cathode materials for advanced lithium-ion batteries that can store solar energy for Australian households and power the next generation electric vehicles. The project will design innovative strategies to suppress the voltage decay and capacity decline of the lithium rich materials over long-term cycling. The project expects to significantly improve ....New high energy density cathode materials for lithium ion batteries. This project aims to develop new high-energy-density and low-cost lithium-rich cathode materials for advanced lithium-ion batteries that can store solar energy for Australian households and power the next generation electric vehicles. The project will design innovative strategies to suppress the voltage decay and capacity decline of the lithium rich materials over long-term cycling. The project expects to significantly improve battery performance at a lower price and make a substantial impact to the energy supply technologies and industries in Australia and benefit the environment in the long run.Read moreRead less
Thin combinatorial films for heat management in microelectronics. This project aims to provide a viable solution for heat management in microelectronics by using highly efficient Peltier devices made with thin combinatorial films. Heat generated by electric current, which is ubiquitous in microelectronic devices, has become increasingly problematic for high density charge-based logical circuitries. The project will significantly enhance the energy conversion efficiency of Peltier devices by opti ....Thin combinatorial films for heat management in microelectronics. This project aims to provide a viable solution for heat management in microelectronics by using highly efficient Peltier devices made with thin combinatorial films. Heat generated by electric current, which is ubiquitous in microelectronic devices, has become increasingly problematic for high density charge-based logical circuitries. The project will significantly enhance the energy conversion efficiency of Peltier devices by optimising the interdependent electron and phonon transports, simultaneously, with a new concept of thin combinatorial films for heat management in microelectronic devices. This is expected to facilitate the development of novel materials in Australia, with access to a large global market.Read moreRead less
Nanostructured Electrocatalysts for Clean Fuels Production. This project aims to develop single-component and hybrid transition-metal and metal-free electrocatalysts with controllable nanostructures to efficiently and selectively catalyse carbon dioxide reduction and hydrogen evolution reactions for clean fuels production including hydrogen and low-carbon organic molecules. By combining experimental and theoretical modelling, this project plans to reveal the origins, mechanism and pathway of the ....Nanostructured Electrocatalysts for Clean Fuels Production. This project aims to develop single-component and hybrid transition-metal and metal-free electrocatalysts with controllable nanostructures to efficiently and selectively catalyse carbon dioxide reduction and hydrogen evolution reactions for clean fuels production including hydrogen and low-carbon organic molecules. By combining experimental and theoretical modelling, this project plans to reveal the origins, mechanism and pathway of these reactions, and the effect of catalyst composition and morphology on their performance. The resulting nanostructured catalysts are of great importance for feasible clean fuel generation and carbon dioxide reduction.Read moreRead less
Beyond Phononic Crystals-Building New Concepts to Enhance Thermoelectricity. Waste heat, which is discharged into the environment from industrial plants and vehicle exhausts, represents a huge amount of lost energy and is a major contributor to global warming. Thermoelectric materials, which can generate electricity from the waste heat, could play an important role in a global sustainable energy solution while reducing greenhouse emissions. This program is aimed at experimental and theoretical d ....Beyond Phononic Crystals-Building New Concepts to Enhance Thermoelectricity. Waste heat, which is discharged into the environment from industrial plants and vehicle exhausts, represents a huge amount of lost energy and is a major contributor to global warming. Thermoelectric materials, which can generate electricity from the waste heat, could play an important role in a global sustainable energy solution while reducing greenhouse emissions. This program is aimed at experimental and theoretical development of new concepts to engineer the interfaces with various atomic stacking sequence of two complex oxides and also the three-dimensional binary nanocube superlattices to enhance the energy conversion efficiency of oxide based thermoelectric materials by several times over today's state-of-the-art.Read moreRead less
Nanostructured non-precious metal and metal-free catalysts for sustainable clean energy generation. The innovative technologies for substitution of precious metal catalysts will be developed and used in fuel cells for clean energy generation in a highly efficient and sustainable form. This effort will lead to the reduction in carbon dioxide emissions and the alleviation of environmental and climate change problems.