Industrial Transformation Research Hubs - Grant ID: IH230100005
Funder
Australian Research Council
Funding Amount
$5,000,000.00
Summary
ARC Research Hub in Zero-emission Power Generation for Carbon Neutrality. This Hub aims to develop sustainable zero-emission power generation technologies to transform gaseous waste (mainly CO2) from our energy and manufacturing sectors into valuable products and create scalable pathways to market for driving industry transformation. This Hub expects to harvest renewable energy from the environment by using zero-emission power generators and then store it in green and safer batteries for convert ....ARC Research Hub in Zero-emission Power Generation for Carbon Neutrality. This Hub aims to develop sustainable zero-emission power generation technologies to transform gaseous waste (mainly CO2) from our energy and manufacturing sectors into valuable products and create scalable pathways to market for driving industry transformation. This Hub expects to harvest renewable energy from the environment by using zero-emission power generators and then store it in green and safer batteries for converting gaseous waste from sectors that cannot easily avoid emission into useful chemicals, which in turn realize carbon neutrality and negativity. The outcomes of this Hub are likely to be transformative for industry, the economy, and society in new-type renewable energy resources through decreasing environmental pollutants. Read moreRead less
Bioinspired Nanoionic Materials for Watt-scale Nano-Hydroelectric Generator. Inspired by electric eels, this project aims to develop next generation flexible and eco-friendly power sources that can directly generate electricity from water droplets for self-powered, light-weight wearable electronics. The goal will be achieved by designing a new class of nanoionic materials for nano-hydroelectric generators, through optimizing the ion diffusion channel, interfacial architecture, electrode configu ....Bioinspired Nanoionic Materials for Watt-scale Nano-Hydroelectric Generator. Inspired by electric eels, this project aims to develop next generation flexible and eco-friendly power sources that can directly generate electricity from water droplets for self-powered, light-weight wearable electronics. The goal will be achieved by designing a new class of nanoionic materials for nano-hydroelectric generators, through optimizing the ion diffusion channel, interfacial architecture, electrode configuration, and power management systems. The expected outcomes will be new nanoionic materials for a wide range of end uses in portable power supply with much higher capacity compared with conventional thin film batteries, significant advances in wearable electronics, and advancing knowledge in energy conversion sector.
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Carbon fibre thermoplastics as next-generation carbon fibre composites. By combining sizing, chemical grafting, and nano-reinforcement strategies, this project develops chemically and thermally robust thermoplastic interfacial sizing for carbon fiber/thermoplastic composites for rapid manufacturing. Thermostamped carbon fiber/thermoplastic composite prototypes will be used to verify the sizing. In order to demonstrate industrial viability, recyclability and reprocessability analyses will be cond ....Carbon fibre thermoplastics as next-generation carbon fibre composites. By combining sizing, chemical grafting, and nano-reinforcement strategies, this project develops chemically and thermally robust thermoplastic interfacial sizing for carbon fiber/thermoplastic composites for rapid manufacturing. Thermostamped carbon fiber/thermoplastic composite prototypes will be used to verify the sizing. In order to demonstrate industrial viability, recyclability and reprocessability analyses will be conducted. This sizing method can enable high-performance thermoplastic composites in nonaerospace applications with its atomistic level modelling and comprehensive characterisation routine. A key objective of this study is to produce sustainably manufactured composite materials that are also commercially relevant.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101617
Funder
Australian Research Council
Funding Amount
$434,395.00
Summary
Re-engineering metallic-based nanostructures for carbon dioxide conversion. This project aims to fine-tune the interface of low-temperature liquid metals to produce functional hybrid nanomaterials for CO2 reduction. The expected outcomes of the projects are to develop fundamental knowledge on the integration of functional molecules on the bulk, core, and skin of liquid metals and their alloys. It intends to control the atomic arrangement of the elemental constituents, nucleation, as well as inte ....Re-engineering metallic-based nanostructures for carbon dioxide conversion. This project aims to fine-tune the interface of low-temperature liquid metals to produce functional hybrid nanomaterials for CO2 reduction. The expected outcomes of the projects are to develop fundamental knowledge on the integration of functional molecules on the bulk, core, and skin of liquid metals and their alloys. It intends to control the atomic arrangement of the elemental constituents, nucleation, as well as interaction and dissolution of organic/inorganic molecules in the interface and bulk of liquid metals. The anticipated outcomes of this project are to define a knowledge roadmap to exploit the untapped potentials of liquid metals in CO2 reduction, which would enable the production of the next generation of catalytic devices.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101068
Funder
Australian Research Council
Funding Amount
$454,554.00
Summary
Direct Electrolysis of Amine Captured CO2 for Producing Syngas. This project aims to develop electrolysis of amine captured carbon dioxide (CO2) technology to integrate CO2 capture and syngas production powered by renewable electricity. The aqueous amine captured CO2 will be directly electrolysed without CO2 desorption, compression, and purification, featuring extremely high efficiency and cost-effectiveness. Expected outcomes include the delivery of suitable amines, a family of chemically and s ....Direct Electrolysis of Amine Captured CO2 for Producing Syngas. This project aims to develop electrolysis of amine captured carbon dioxide (CO2) technology to integrate CO2 capture and syngas production powered by renewable electricity. The aqueous amine captured CO2 will be directly electrolysed without CO2 desorption, compression, and purification, featuring extremely high efficiency and cost-effectiveness. Expected outcomes include the delivery of suitable amines, a family of chemically and structurally controlled electrocatalysts, an in-depth understanding of CO2 electrolysis mechanisms, and the demonstration of robust electrolyser prototypes. This project will provide significant benefits to Australia’s energy and environmental security, and boost its clean energy industry and economic growth.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101396
Funder
Australian Research Council
Funding Amount
$360,218.00
Summary
Designing Single-atom catalysts for Renewable Waste Conversion to Urea. This DECRA aims to realise the direct electrochemical conversion of waste resources using renewable energy to generate urea at ambient conditions. By designing impurity-tolerant single atom catalysts and unearthing their structure-activity relationships, the utilisation of flue gas and wastewater will be materialised. This will advance our understanding in the field as current energy conversion reactions require pure feedsto ....Designing Single-atom catalysts for Renewable Waste Conversion to Urea. This DECRA aims to realise the direct electrochemical conversion of waste resources using renewable energy to generate urea at ambient conditions. By designing impurity-tolerant single atom catalysts and unearthing their structure-activity relationships, the utilisation of flue gas and wastewater will be materialised. This will advance our understanding in the field as current energy conversion reactions require pure feedstocks. Expected outcomes from the program is envisioned to lead to deployment of scalable decentralised modes of green urea production (substituting imports), and the knowledge transferrable to other areas of Australia’s emerging hydrogen economy, extending the scope of renewable Power-to-X to realise a circular economy.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
Upcycling of mixed plastics from bioprocessed municipal solid waste. This project aims to develop a scalable catalytic process that can sustainably upcycle mixed plastics from bioprocessed municipal solid waste into hydrogen and valuable carbon nanotube products. The process will integrate pyrolysis, reforming, and carbon growth technology into a single reactor, enabled by the rational design of multifunctional catalysts. Through computational process simulation and optimization, life cycle anal ....Upcycling of mixed plastics from bioprocessed municipal solid waste. This project aims to develop a scalable catalytic process that can sustainably upcycle mixed plastics from bioprocessed municipal solid waste into hydrogen and valuable carbon nanotube products. The process will integrate pyrolysis, reforming, and carbon growth technology into a single reactor, enabled by the rational design of multifunctional catalysts. Through computational process simulation and optimization, life cycle analysis, and techno-economic assessment, investment and operational costs at larger scale are anticipated to be greatly reduced. By mitigating mixed waste plastics from going to landfills, the project will also provide significant benefits to clean energy production and advanced material manufacturing in Australia. Read moreRead less