Targeted synthesis of porous materials towards gas sorption and separation. Targeted synthesis, using a building block strategy and computational design, is an efficient method for controlled synthesis of porous materials. This project uses this method to synthesise porous materials with permanent functional pores for separating and storing fuels and greenhouse gases, addressing demanding energy and environmental problems.
New high performance zinc bromine batteries with novel electrode/electrolyte systems. Renewable sources of energy are of particular interest in the era of diminishing fossil fuels. Efficient energy storage is a missing link for renewable energy. Zinc-bromine batteries have great potential as energy storage. This project will aim to fundamentally re-design the existing first generation systems to improve power density by 300-400 per cent.
Efficient ionic liquid-based reduction of nitrogen to ammonia. This project aims to develop a hybrid ionic liquid-nanostructured electrode platform to electrochemically convert nitrogen gas to ammonia. Ammonia production, mostly for fertilisers, consumes more than 1% of the global energy supply and contributes 1.6 % of global carbon dioxide emissions. A process that could convert nitrogen to ammonia using renewable energy would be an important alternative approach. This project will develop a pl ....Efficient ionic liquid-based reduction of nitrogen to ammonia. This project aims to develop a hybrid ionic liquid-nanostructured electrode platform to electrochemically convert nitrogen gas to ammonia. Ammonia production, mostly for fertilisers, consumes more than 1% of the global energy supply and contributes 1.6 % of global carbon dioxide emissions. A process that could convert nitrogen to ammonia using renewable energy would be an important alternative approach. This project will develop a platform for electrochemical conversion of nitrogen gas to ammonia and optimise it for use with surplus renewable energy supplies. The project is expected to contribute to mitigation of greenhouse emissions and create a technology for distributed production of ammonia and ammonium fertilisers.Read moreRead less
Advanced framework materials for hydrogen storage applications. This project aims to develop new molecular materials capable of the highly efficient storage of hydrogen gas. Through an innovative interdisciplinary approach that targets the synthesis and detailed characterisation of two classes of molecular material this project expects to generate step-change advances in the understanding of how hydrogen gas uptake relates to the chemical and physical attributes of porous molecular systems. Sign ....Advanced framework materials for hydrogen storage applications. This project aims to develop new molecular materials capable of the highly efficient storage of hydrogen gas. Through an innovative interdisciplinary approach that targets the synthesis and detailed characterisation of two classes of molecular material this project expects to generate step-change advances in the understanding of how hydrogen gas uptake relates to the chemical and physical attributes of porous molecular systems. Significant anticipated outcomes and benefits include the development of new material design approaches that optimise performance across a diverse parameter space, and the generation of advanced new materials worthy of commercial development, spanning small scale mobile to large scale stationary storage applications.Read moreRead less
Phosphonium ionic liquids for advanced lithium energy storage systems. This project will develop, along with a leading manufacturer in the world, high performance electrolytes for lithium batteries. The technologies and expertise generated will be of importance to many niche industries in Australia in their shift towards lower carbon operations.
Discovery Early Career Researcher Award - Grant ID: DE210101618
Funder
Australian Research Council
Funding Amount
$417,000.00
Summary
Designing supramolecular compounds for sustainable energy storage. The project aims to create a new strategy for designing redox-active supramolecular compounds for energy storage devices. The project covers the simultaneous development of electrode-active materials, in-depth characterisation, and cell fabrication by combining supramolecular chemistry and advanced battery engineering. The knowledge anticipated to be accumulated through the project will be a fundamental cornerstone for achieving ....Designing supramolecular compounds for sustainable energy storage. The project aims to create a new strategy for designing redox-active supramolecular compounds for energy storage devices. The project covers the simultaneous development of electrode-active materials, in-depth characterisation, and cell fabrication by combining supramolecular chemistry and advanced battery engineering. The knowledge anticipated to be accumulated through the project will be a fundamental cornerstone for achieving large-scale energy storage devices for renewable energies, and an effective approach for resolving climate change driven by global warming.Read moreRead less
Designing disorder into ionic materials for clean energy applications. . This project aims to develop new materials designed to possess optimum properties for targeted clean energy technologies. By the design of specific ion chemistries, we aim to produce materials that absorb large amounts of thermal energy, as needed in energy storage and refrigeration applications. Their large internal free volume will offer unique properties for energy-consuming gas separation applications. Expected outcomes ....Designing disorder into ionic materials for clean energy applications. . This project aims to develop new materials designed to possess optimum properties for targeted clean energy technologies. By the design of specific ion chemistries, we aim to produce materials that absorb large amounts of thermal energy, as needed in energy storage and refrigeration applications. Their large internal free volume will offer unique properties for energy-consuming gas separation applications. Expected outcomes from the project include (i) fundamental understanding of ion design, (ii) a suite of new materials with advantageous properties for energy application. The expected benefits include advancement of technologies that support renewable energy storage and a reduction in energy costs and harmful emissions from refrigeration.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101627
Funder
Australian Research Council
Funding Amount
$447,625.00
Summary
Developing ultra adsorbent MOF composites as high performance materials. This project aims to improve the adsorption properties of porous materials through enhancing their selectivity and also creating new composites. This research expects to extend application opportunities to encompass real-life scenarios, in particular hydrogen transfer and carbon capture. Expected outcomes is the enhancement of the adsorbent properties of these porous materials, and an improvement of their selectivity and m ....Developing ultra adsorbent MOF composites as high performance materials. This project aims to improve the adsorption properties of porous materials through enhancing their selectivity and also creating new composites. This research expects to extend application opportunities to encompass real-life scenarios, in particular hydrogen transfer and carbon capture. Expected outcomes is the enhancement of the adsorbent properties of these porous materials, and an improvement of their selectivity and mechanical robustness. This is due to the synergistic strengthening effects of new graphene and nanodiamond composites. The benefit of this research is in bridging the gap between porous material synthesis and industrial application, contributing to Australia's becoming a world leader in clean energy research.Read moreRead less
Next-generation solid-state batteries to drive an automotive revolution. This project seeks to design and fabricate new solid-state silicon electrodes for advanced high energy, high stability lithium batteries. It is anticipated that this project will generate new knowledge in the area of battery electrode materials through an innovative combination of a soft plastic crystal electrolyte with a highly conductive glass ceramic electrolyte. Expected outcomes of this project include a greater unders ....Next-generation solid-state batteries to drive an automotive revolution. This project seeks to design and fabricate new solid-state silicon electrodes for advanced high energy, high stability lithium batteries. It is anticipated that this project will generate new knowledge in the area of battery electrode materials through an innovative combination of a soft plastic crystal electrolyte with a highly conductive glass ceramic electrolyte. Expected outcomes of this project include a greater understanding of electrolyte properties and an increase in the electrode cycle stability. This should provide significant benefits, such as the development of a new high capacity battery to promote the uptake of electric vehicles and lower Australia's carbon footprint.Read moreRead less
Black titanium dioxide-graphene nanoleaves drive solid-gas selective carbon dioxide to solar fuels. This project aims to remove carbon dioxide from the atmosphere as part of a reaction to produce a carbon-neutral solar fuel. People are currently still over reliant on fossil fuels for energy production, which leads to increased greenhouse gases and their detrimental climate effect. This project will develop novel wireless sustainable nano-reactors, which can be scaled to a system working in an am ....Black titanium dioxide-graphene nanoleaves drive solid-gas selective carbon dioxide to solar fuels. This project aims to remove carbon dioxide from the atmosphere as part of a reaction to produce a carbon-neutral solar fuel. People are currently still over reliant on fossil fuels for energy production, which leads to increased greenhouse gases and their detrimental climate effect. This project will develop novel wireless sustainable nano-reactors, which can be scaled to a system working in an ambient environment for high-yield production. The expected outcomes are to synthesise nano-flowers composed of 2D functional nano-leaves, which will be fabricated into a flexible large-area carbon dioxide-to-solar fuel system. This project will also expand knowledge in heterojunctions, surface chemistry and nano-manufacturing of 2D materials. The technology to be developed will only rely on natural solar, atmospheric, and earth-abundant eco-friendly resources, and intends to promote Australia as a key regional solar fuels production and export nation.Read moreRead less