Discovery Early Career Researcher Award - Grant ID: DE240101231
Funder
Australian Research Council
Funding Amount
$411,837.00
Summary
Quinoid Polymers for Organic Electrochemical Transistors and Bioelectronics. This project aims to develop organic semiconductors (OSCs) with excellent mechanical flexibility and biocompatibility to exploit their potentials in bioelectronics. It connects the electronic world with ionic world of biology to push the biomedical application of OSCs a big step forward. Interdisciplinary knowledge, intellectual properties (IPs), top-notch publications, invited talks, and international collaborations ar ....Quinoid Polymers for Organic Electrochemical Transistors and Bioelectronics. This project aims to develop organic semiconductors (OSCs) with excellent mechanical flexibility and biocompatibility to exploit their potentials in bioelectronics. It connects the electronic world with ionic world of biology to push the biomedical application of OSCs a big step forward. Interdisciplinary knowledge, intellectual properties (IPs), top-notch publications, invited talks, and international collaborations are expected. Additionally, it will earn Australia a commercial lead in the biomedical sector to attract more talents to serve Australia. This project also matches well with several government’s strategic research priorities, attracting industries to realise IPs transfer to bring “great value for money” to feed back Australia.Read moreRead less
Bioinspired Ceramifiable Fire-Retardant Composite Coatings. This project aims to design bioinspired, adhesive, ceramifiable fire-retardant coatings through understanding their composition-property relationship and fire-retardant mechanism. The fire-retardant coatings are then applied to typical polymer foams to create fire-safe building thermal insulation materials. This project will generate new knowledge in materials science that helps to expedite next-generation advanced fire-retardant coatin ....Bioinspired Ceramifiable Fire-Retardant Composite Coatings. This project aims to design bioinspired, adhesive, ceramifiable fire-retardant coatings through understanding their composition-property relationship and fire-retardant mechanism. The fire-retardant coatings are then applied to typical polymer foams to create fire-safe building thermal insulation materials. This project will generate new knowledge in materials science that helps to expedite next-generation advanced fire-retardant coatings for a variety of flammable substrates. Expected outcomes of this project are cost-effective fire-retardant coatings and fire-safe, inexpensive thermal insulation materials. This project will bring significant economic benefits to Australia and help to create fire-resilient and energy-efficient buildings.Read moreRead less
Mid-Career Industry Fellowships - Grant ID: IM230100132
Funder
Australian Research Council
Funding Amount
$1,060,944.00
Summary
Novel minerals and mix design in low embodied carbon concrete products . Research and development in materials and mix design for concrete building products will target utilisation of abundant and low cost mineral materials including natural clay, hard rock quarry fines and unclassified fly ash resources. New mix design and preparation methods are targeting improved strength and production efficiency with reduced Portland cement and embodied carbon. This technology will be used in the manufactur ....Novel minerals and mix design in low embodied carbon concrete products . Research and development in materials and mix design for concrete building products will target utilisation of abundant and low cost mineral materials including natural clay, hard rock quarry fines and unclassified fly ash resources. New mix design and preparation methods are targeting improved strength and production efficiency with reduced Portland cement and embodied carbon. This technology will be used in the manufacture of concrete blocks, roof tiles and brick and block mortar products currently manufactured by Brickworks. Outcomes are efficient and sustainable full scale manufacture of higher value, low embodied carbon, lightweight, large format and/or high durability products that are not currently available to the Australian market.Read moreRead less
Fire-Retardant Composite Resins for Bushfire-Safe Wind Farm Infrastructures. This project aims to develop advanced fire-retardant composite resins for manufacturing bushfire-safe wind farm infrastructures. The innovation of the project is the development of a new class of low-cost, novel, highly effective fire retardants and their value-added fire-retardant composite resins with well-preserved physical properties. This will be achieved by understanding the composition-property relationship of fi ....Fire-Retardant Composite Resins for Bushfire-Safe Wind Farm Infrastructures. This project aims to develop advanced fire-retardant composite resins for manufacturing bushfire-safe wind farm infrastructures. The innovation of the project is the development of a new class of low-cost, novel, highly effective fire retardants and their value-added fire-retardant composite resins with well-preserved physical properties. This will be achieved by understanding the composition-property relationship of fire retardants and optimising their synthetic parameters. The project will help position Australia’s advanced composite manufacturing at the forefront of technology. It will also accelerate Australia’s energy transition to renewables by enabling bushfire-safe wind farm infrastructure.Read moreRead less
Thermoelectric devices for high-performing localised coolers. This project aims to develop a lightweight, low-energy-consumption, and high-durability wearable thermoelectric cooler for localised cooling using a novel industry-led approach, coupled with device design and materials engineering strategies. The key breakthrough expected is to design wearable thermoelectric coolers by using flexible substrates and thermoelectric materials with engineered chemistry and unique structures for achieving ....Thermoelectric devices for high-performing localised coolers. This project aims to develop a lightweight, low-energy-consumption, and high-durability wearable thermoelectric cooler for localised cooling using a novel industry-led approach, coupled with device design and materials engineering strategies. The key breakthrough expected is to design wearable thermoelectric coolers by using flexible substrates and thermoelectric materials with engineered chemistry and unique structures for achieving localised, instant, and controllable cooling with super low power input for personal usage in building and mining industry. Expected outcomes include innovative technologies for achieving high-efficiency cooling, which will provide significant economic and commercial benefits for Australia.Read moreRead less
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: DE230101712
Funder
Australian Research Council
Funding Amount
$394,818.00
Summary
All-perovskite tandem solar cells for efficient green hydrogen production. This project aims to design functional materials for the development high-performance and durable solar energy conversion devices, which enable efficient green solar hydrogen production to reduce fossil fuel consumption and alleviate environmental burden. The expected outcomes include advanced semiconducting materials, proof-of-concept solar-driven water electrolytic system with a high solar-to-hydrogen conversion efficie ....All-perovskite tandem solar cells for efficient green hydrogen production. This project aims to design functional materials for the development high-performance and durable solar energy conversion devices, which enable efficient green solar hydrogen production to reduce fossil fuel consumption and alleviate environmental burden. The expected outcomes include advanced semiconducting materials, proof-of-concept solar-driven water electrolytic system with a high solar-to-hydrogen conversion efficiency, and cutting-edge knowledge in material science, physical chemistry, and nanotechnology. The success of this project expects to facilitate pilot-scale green hydrogen industry and thus position Australia at the frontier of advanced materials, clean energy, and renewable hydrogen supply technologies.Read moreRead less