Industrial Transformation Research Hubs - Grant ID: IH200100035
Funder
Australian Research Council
Funding Amount
$5,000,000.00
Summary
ARC Research Hub in New Safe and Reliable Energy Storage and Conversion Technologies. This Research Hub addresses safety and reliability issues, and environmental impact of current energy storage and conversion technologies. The research will deliver a new generation of technologies for storage from small scale portable devices to large scale industrial applications, using recycled and natural materials, and eliminating the serious fire risk in current technologies. Outcomes include innovative ....ARC Research Hub in New Safe and Reliable Energy Storage and Conversion Technologies. This Research Hub addresses safety and reliability issues, and environmental impact of current energy storage and conversion technologies. The research will deliver a new generation of technologies for storage from small scale portable devices to large scale industrial applications, using recycled and natural materials, and eliminating the serious fire risk in current technologies. Outcomes include innovative integrated energy conversion and storage technologies and new energy materials and devices designed for different scale applications, leading to creation of start up companies and commercialisation opportunities for existing partners, benefiting both the Australian economy and potentially transforming the energy industry landscape.Read moreRead less
Engineering Nanoionic Interfaces towards High Performance Cathode Coatings. This project aims to develop novel cathode coating materials towards more durable and powerful energy storage devices. Lithium ion battery will be constructed based on perovskite oxides to provide high capacity and stability for potential applications in electric cars, mobile phones and internet of things. The project will address fundamental challenges in this field by developing high voltage cathode coated with nanoion ....Engineering Nanoionic Interfaces towards High Performance Cathode Coatings. This project aims to develop novel cathode coating materials towards more durable and powerful energy storage devices. Lithium ion battery will be constructed based on perovskite oxides to provide high capacity and stability for potential applications in electric cars, mobile phones and internet of things. The project will address fundamental challenges in this field by developing high voltage cathode coated with nanoionic thin layers. Combined with new materials fabrication techniques and innovative strain engineering, the expected outcome is high performance cathodes with enhanced rate capability and cycling life, low fabrication cost and production scalability.
Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101103
Funder
Australian Research Council
Funding Amount
$397,286.00
Summary
Stable Lithium-Sodium Metal Anodes for Rechargeable Alkali Metal Batteries. The project aims to address the safety issues derived from the dendritic growth and volume variation of alkali metal anodes, which are a challenge for the practical application of rechargeable alkali metal batteries. This project seeks to design a novel 3D lithium/sodium host featuring a lithiophilic-lithiophobic gradient interfacial layer to achieve uniform deposition and structural stability. The expected outcome of th ....Stable Lithium-Sodium Metal Anodes for Rechargeable Alkali Metal Batteries. The project aims to address the safety issues derived from the dendritic growth and volume variation of alkali metal anodes, which are a challenge for the practical application of rechargeable alkali metal batteries. This project seeks to design a novel 3D lithium/sodium host featuring a lithiophilic-lithiophobic gradient interfacial layer to achieve uniform deposition and structural stability. The expected outcome of this project is to successfully develop alkali metal batteries that are stable, safe and have high energy density. This project should have significant benefits such as the advancement of knowledge in alkali metal batteries and strengthen Australia’s competitiveness in the area of next-generation energy storage technologies.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100680
Funder
Australian Research Council
Funding Amount
$423,275.00
Summary
Solar electrolysis for manufacture of sustainable energy storage materials. This project aims to develop a novel solar-driven manufacturing process able to produce advanced carbon materials which effectively sequester carbon dioxide (negative emission). The project expects to provide key data and insights into a new method of carbon capture and utilisation through advancement of the fundamental science of carbon electrolysis and carbonate regeneration. A combination of advanced electrochemical a ....Solar electrolysis for manufacture of sustainable energy storage materials. This project aims to develop a novel solar-driven manufacturing process able to produce advanced carbon materials which effectively sequester carbon dioxide (negative emission). The project expects to provide key data and insights into a new method of carbon capture and utilisation through advancement of the fundamental science of carbon electrolysis and carbonate regeneration. A combination of advanced electrochemical and engineering techniques will be utilised to achieve this from lab-scale experimental work through to process modelling. Expected outcomes of this project include a clear understanding of the practical potential of this negative emission technology in contributing to offsetting global carbon dioxide emissions.Read moreRead less
Thermal transport in multi-phase flows for concentrating solar applications. This project seeks to advance the field of heat transfer in high-temperature systems involving liquid metals, with emphasis on energy storage and solar power technologies. The concept couples a tubular sodium boiler with a sodium chloride phase-change storage system for continuous energy supply. Sodium chloride is low cost and has a melting temperature suitable for a wide range of industrial processes. The project plans ....Thermal transport in multi-phase flows for concentrating solar applications. This project seeks to advance the field of heat transfer in high-temperature systems involving liquid metals, with emphasis on energy storage and solar power technologies. The concept couples a tubular sodium boiler with a sodium chloride phase-change storage system for continuous energy supply. Sodium chloride is low cost and has a melting temperature suitable for a wide range of industrial processes. The project plans to address the challenge of sodium stability in highly irradiated tubes by investigating mass, momentum, energy and radiative transport in liquid metals. It is intended that this will inform the design and testing of novel sodium boilers to provide stable and isothermal process heat for continuous or on-demand production of power, chemical fuels and commodities.Read moreRead less
General systems modelling of hydrogen production network in Australia. The project aims at further developing a general framework for systems modelling and applying the framework to investigate the feasibility and sustainability of large-scale hydrogen production in Australia. Two pathways proposed in this project are to be examined: 1) hybrid plants sourcing hydrogen from fossil fuels and solar thermal energy and 2) hydrogen production network producing hydrogen from 100% renewable energy. The ....General systems modelling of hydrogen production network in Australia. The project aims at further developing a general framework for systems modelling and applying the framework to investigate the feasibility and sustainability of large-scale hydrogen production in Australia. Two pathways proposed in this project are to be examined: 1) hybrid plants sourcing hydrogen from fossil fuels and solar thermal energy and 2) hydrogen production network producing hydrogen from 100% renewable energy. The project involves building systems models and using these models to determine optimal operational parameters and conditions with the goal of maintaining export of high-end energy resources to Japan and other countries as well as using hydrogen domestically while minimising the environment effects of hydrogen production.Read moreRead less
Sustainable high energy sodium batteries with enhanced safety & cycle life. This project aims to deliver a high specific energy, ambient temperature sodium metal battery that is more sustainable, safer and better performing than existing technologies. Innovative chemistry will be used to replace the current flammable and toxic organic solvent-based systems, while novel tools and capabilities will be forged to retain Australian leadership in this sector. These advances will provide a technology ....Sustainable high energy sodium batteries with enhanced safety & cycle life. This project aims to deliver a high specific energy, ambient temperature sodium metal battery that is more sustainable, safer and better performing than existing technologies. Innovative chemistry will be used to replace the current flammable and toxic organic solvent-based systems, while novel tools and capabilities will be forged to retain Australian leadership in this sector. These advances will provide a technology and materials platform to generate and support emerging energy storage industries in Australia. It will strengthen international collaborations with leading research teams and provide opportunities and training for the next generation of energy storage research leaders in both academia and industry.Read moreRead less
Novel Fuel Materials for Radiation-Free Proton-Boron Fusion Power Source. Laser proton-boron fusion reactions are a radiation-free nuclear energy source but are limited by a low reaction rate due to a lack of efficient fuel materials. This project aims to develop new fuel materials by synthesising isotope boron 11 enriched hydrogen borides and hydrogen adsorbed boron nitride nanosheets using our research experience in hydrogen storage and nanomateials synthesis. The expected outcomes include tw ....Novel Fuel Materials for Radiation-Free Proton-Boron Fusion Power Source. Laser proton-boron fusion reactions are a radiation-free nuclear energy source but are limited by a low reaction rate due to a lack of efficient fuel materials. This project aims to develop new fuel materials by synthesising isotope boron 11 enriched hydrogen borides and hydrogen adsorbed boron nitride nanosheets using our research experience in hydrogen storage and nanomateials synthesis. The expected outcomes include two new hydrogen storage nanomaterials, the associated new synthesis technologies, and a clean and safe nuclear power source, which helps to reduce carbon dioxide emissions.Read moreRead less
High-voltage electrode materials for lithium-ion batteries. This project aims to establish a complete battery research system and develop high-voltage electrode materials for lithium-ion batteries through mechanistic understanding obtained in operando studies. Lithium-ion batteries are the most promising choice for portable electronic devices, including electric vehicles, due to their high power and energy performance compared with other battery technologies. The success of this project is expec ....High-voltage electrode materials for lithium-ion batteries. This project aims to establish a complete battery research system and develop high-voltage electrode materials for lithium-ion batteries through mechanistic understanding obtained in operando studies. Lithium-ion batteries are the most promising choice for portable electronic devices, including electric vehicles, due to their high power and energy performance compared with other battery technologies. The success of this project is expected to advance fundamental understanding of lithium-ion batteries, and provide techniques to develop a promising high-energy and high-power battery system.Read moreRead less
Laser nanoprinting of active graphene micro-tag for terahertz digital ID. This project aims at harnessing the unique THz response of laser nanoprinted graphene metamaterials and developing disruptive micro-tag technology. Through actively tuning the structured metamaterials, THz micro-tags with ultrahigh data security and energy efficiency, low cost, flexibility and attachable to any object can be enabled. Such high performance graphene THz ID tags will be first of their kind and are expected t ....Laser nanoprinting of active graphene micro-tag for terahertz digital ID. This project aims at harnessing the unique THz response of laser nanoprinted graphene metamaterials and developing disruptive micro-tag technology. Through actively tuning the structured metamaterials, THz micro-tags with ultrahigh data security and energy efficiency, low cost, flexibility and attachable to any object can be enabled. Such high performance graphene THz ID tags will be first of their kind and are expected to underpin every sector of our life including manufacturing, logistics, biomedicine, personal care, supply chain, retail and security. The outcomes will secure Australia’s international leading position in next generation tag and digitalisation technology and create significant social and economic benefits to Australians.Read moreRead less