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
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
Solar-thermal desalination system for parallel water-electricity generation. This project aims to develop a multi-functional solar-thermal desalination device to simultaneously produce clean water and electricity. Interfacial solar evaporation-based desalination technology has the unique advantage of using solar light as the sole energy source for affordable clean water production. However, its absolute evaporation rate is still too low for practical application and all of the latent heat releas ....Solar-thermal desalination system for parallel water-electricity generation. This project aims to develop a multi-functional solar-thermal desalination device to simultaneously produce clean water and electricity. Interfacial solar evaporation-based desalination technology has the unique advantage of using solar light as the sole energy source for affordable clean water production. However, its absolute evaporation rate is still too low for practical application and all of the latent heat released from vapor condensation during desalination is wasted. Solving these two critical issues by the study of energy nexus, design and fabrication of advanced photothermal materials and desalination devices could accelerate practical adoption of this technology and benefit millions of people who desperately need clean water. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100521
Funder
Australian Research Council
Funding Amount
$415,000.00
Summary
Engineering semitransparent perovskite solar cells for smart solar windows. This project aims to develop highly efficient and stable semitransparent perovskite solar cells for innovative smart solar windows. The key concept is to explore novel functionalisation strategies on emerging carbon and two-dimensional materials to fabricate semitransparent perovskite solar cells for self-powered smart photovoltaic windows. Expected outcomes of this project include not only placing Australia at the foref ....Engineering semitransparent perovskite solar cells for smart solar windows. This project aims to develop highly efficient and stable semitransparent perovskite solar cells for innovative smart solar windows. The key concept is to explore novel functionalisation strategies on emerging carbon and two-dimensional materials to fabricate semitransparent perovskite solar cells for self-powered smart photovoltaic windows. Expected outcomes of this project include not only placing Australia at the forefront of research in the fields of materials science and renewable energy, but also creating commercial opportunities in Australia. This project expects to have various benefits for Australians – through the development of a cutting-edge sustainable energy device and the establishment of strong international collaborations.Read moreRead less
Advanced all-Iron flow batteries for stationary energy storage. Iron flow batteries are one of the most promising choices for clean, reliable and cost effective long-duration energy storage. The main obstacle for large scale commercial deployment is the low round-trip energy efficiency caused by the competitive side reaction that occurs at the negative electrode during battery charging. The project aims to address this issue by engineering the negative electrode-electrolyte interface with functi ....Advanced all-Iron flow batteries for stationary energy storage. Iron flow batteries are one of the most promising choices for clean, reliable and cost effective long-duration energy storage. The main obstacle for large scale commercial deployment is the low round-trip energy efficiency caused by the competitive side reaction that occurs at the negative electrode during battery charging. The project aims to address this issue by engineering the negative electrode-electrolyte interface with functional materials to improve battery performance and thus further reduce the cost of energy storage. Expected outcomes include new materials and methods for advanced battery technology and manufacturing. The success of the project will significantly support the national priority of net-zero carbon emissions by 2050.Read moreRead less
Functional biomass carbons for low-cost sodium and potassium-ion batteries. The development of hard carbon anode materials for stationary rechargeable sodium and potassium ion batteries remains a major technological challenge. This project aims to utilise two very different biomass feedstock sources, sorghum and macadamia shell agricultural waste to manufacture low-cost, high-performance carbon anodes. Current carbon anode materials such as graphite or carbonised sucrose, pitch or phenolics suff ....Functional biomass carbons for low-cost sodium and potassium-ion batteries. The development of hard carbon anode materials for stationary rechargeable sodium and potassium ion batteries remains a major technological challenge. This project aims to utilise two very different biomass feedstock sources, sorghum and macadamia shell agricultural waste to manufacture low-cost, high-performance carbon anodes. Current carbon anode materials such as graphite or carbonised sucrose, pitch or phenolics suffer from poor performance, high cost and/or low carbon yield and device durability issues. This project will investigate combinations of biomass precursors, tailored graphene and carbon alloys in order to significantly enhance anode performance while minimising cost.Read moreRead less
Advanced Gas Diffusion Electrodes For Electrochemical Manufacturing. This project aims to develop electrochemical conversion technologies to convert carbon dioxide into globally needed chemicals. It targets the bottleneck issues in managing the gas-liquid-solid reaction sites and improving the conversion efficiency of reactor, through the synthesis of advanced electrode materials, understanding of mass transfer and the engineering design of an electrochemical reactor. The expected outcomes will ....Advanced Gas Diffusion Electrodes For Electrochemical Manufacturing. This project aims to develop electrochemical conversion technologies to convert carbon dioxide into globally needed chemicals. It targets the bottleneck issues in managing the gas-liquid-solid reaction sites and improving the conversion efficiency of reactor, through the synthesis of advanced electrode materials, understanding of mass transfer and the engineering design of an electrochemical reactor. The expected outcomes will promote carbon neutral goals, bridge the renewable energy storage and sustainable chemical manufacturing gap, thus addressing key challenges faced by Australia and the world.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100794
Funder
Australian Research Council
Funding Amount
$419,000.00
Summary
Prediction of new electrolytes for improved electrical energy storage. This project aims to identify new electrolyte solutions with suitable properties for use in improved electrical energy storage technologies. Identifying new electrolyte solutions is a crucial challenge for improving the performance of many technologies including energy storage. This project applies quantum mechanical calculation to develop a fast, accurate and predictive model of the properties of electrolyte solutions. High ....Prediction of new electrolytes for improved electrical energy storage. This project aims to identify new electrolyte solutions with suitable properties for use in improved electrical energy storage technologies. Identifying new electrolyte solutions is a crucial challenge for improving the performance of many technologies including energy storage. This project applies quantum mechanical calculation to develop a fast, accurate and predictive model of the properties of electrolyte solutions. High throughput computational screening based on this model can then identify new electrolytes that can be used in technologies such as energy storage. This should give Australia a competitive edge in the rapidly growing energy storage industry, while also accelerating the shift away from harmful fossil fuels. Read moreRead less
Solar rechargeable Zinc-Bromine Flow Batteries. This project aims to develop a new solar rechargeable Zinc-Bromine flow battery for better utilization of the abundant yet intermittently available sunlight. The key design is to create a solar-driven photoelectrochemical process to convert the discharged electrode materials back to their charged states and realise the direct storage of solar energy. Expected outcomes include new solar driven rechargeable technology and photoelectrode materials, as ....Solar rechargeable Zinc-Bromine Flow Batteries. This project aims to develop a new solar rechargeable Zinc-Bromine flow battery for better utilization of the abundant yet intermittently available sunlight. The key design is to create a solar-driven photoelectrochemical process to convert the discharged electrode materials back to their charged states and realise the direct storage of solar energy. Expected outcomes include new solar driven rechargeable technology and photoelectrode materials, as well as new knowledge generated from collaborations across materials science, photoelectrochemistry and nanotechnology disciplines. Further advances in functional materials for solar energy storage will assist in addressing the global energy shortage and mitigating environmental pollution.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240101090
Funder
Australian Research Council
Funding Amount
$433,217.00
Summary
In-depth Investigation of Lithium Dendrite Formation Processes. Battery failure is mainly derived from uncontrollable lithium dendrite formation. This project aims to investigate fundamental lithium dendrite formation mechanism by utilizing a novel in-situ transmission electron microscopy cell. This project expects to build a new set up which is capable of simultaneous in-situ electrical and nanomechanical measurements of lithium dendrite growth. This project aims to reveal how lithium dendrite ....In-depth Investigation of Lithium Dendrite Formation Processes. Battery failure is mainly derived from uncontrollable lithium dendrite formation. This project aims to investigate fundamental lithium dendrite formation mechanism by utilizing a novel in-situ transmission electron microscopy cell. This project expects to build a new set up which is capable of simultaneous in-situ electrical and nanomechanical measurements of lithium dendrite growth. This project aims to reveal how lithium dendrite growth is affected by different surface modifications on the commercial graphite electrodes. The success of the project will lead to a fundamental understanding of the lithium dendrite formation mechanism, enabling the construction of significantly safer batteries.Read moreRead less