Flame-Retarding and Mechanically Resilient Elastomer Composites. This project will develop a new generation of flame-retarding and mechanically resilient elastomer composites by taking advantage of nanoscale effect and synergy. The outcomes will be two types of flame-retarding additive pellets and their elastomer composites; these pellets also suit other polymers such as thermoplastics. The elastomer composites are expected to have excellent flame retardancy, mechanical properties, and fatigue p ....Flame-Retarding and Mechanically Resilient Elastomer Composites. This project will develop a new generation of flame-retarding and mechanically resilient elastomer composites by taking advantage of nanoscale effect and synergy. The outcomes will be two types of flame-retarding additive pellets and their elastomer composites; these pellets also suit other polymers such as thermoplastics. The elastomer composites are expected to have excellent flame retardancy, mechanical properties, and fatigue performance, to meet the demands from industrial partners. The project will provide a platform for elastomer manufacturing industry to develop flame-retarding, high-performance products for domestic applications and for export. Read moreRead less
Autonomous Discovery of Green Inhibitors. The project aims to develop autonomous material design by integrating evolutionary algorithms and robotic experimentation. The project expects to pioneer a new method of materials discovery that could cut discovery times to 20% of traditional methods. Its expected to have significance through its discovery of new classes of corrosion inhibitors that are safe to both humans and the environment. The expected outcomes of this project will be a rapid disc ....Autonomous Discovery of Green Inhibitors. The project aims to develop autonomous material design by integrating evolutionary algorithms and robotic experimentation. The project expects to pioneer a new method of materials discovery that could cut discovery times to 20% of traditional methods. Its expected to have significance through its discovery of new classes of corrosion inhibitors that are safe to both humans and the environment. The expected outcomes of this project will be a rapid discovery methodology that can be used across materials science and new classes of safe corrosion inhibitors. This should provide significant benefits to workplace n safety and the environmental impact of the coatings industry while also increasing the rapid of innovation of new materials.Read moreRead less
Tandem Photocatalytic Conversion of CO2 to High Value Hydrocarbon Products. Converting carbon dioxide (CO2) into hydrocarbon products is ideal for combating anthropogenic emissions whilst reducing our reliance on fossil fuels. Despite the significant advantages, CO2 valorisation is hindered by barriers such as high energy requirements and low-value products (methane and carbon monoxide). This project will establish a sustainable approach to CO2 valorisation using a unique tandem solar-driven hie ....Tandem Photocatalytic Conversion of CO2 to High Value Hydrocarbon Products. Converting carbon dioxide (CO2) into hydrocarbon products is ideal for combating anthropogenic emissions whilst reducing our reliance on fossil fuels. Despite the significant advantages, CO2 valorisation is hindered by barriers such as high energy requirements and low-value products (methane and carbon monoxide). This project will establish a sustainable approach to CO2 valorisation using a unique tandem solar-driven hierarchical catalyst array to offset energy requirements and directly yield high-value hydrocarbon products, such as ethane (C2H6) and ethanol (CH3CH2OH), from captured CO2.Read moreRead less
In-situ grain boundary engineering via metal additive manufacturing. We aim to develop a capability for targeted specialty alloy microstructure design via metal 3D printing. Our approach to generate customised grain boundary networks in stainless steels and superalloys will unlock superior mechanical, corrosion and technological properties, without subsequent thermomechanical treatments. Scientific outcomes are new physical metallurgy knowledge on the targeted selection of desirable interfaces v ....In-situ grain boundary engineering via metal additive manufacturing. We aim to develop a capability for targeted specialty alloy microstructure design via metal 3D printing. Our approach to generate customised grain boundary networks in stainless steels and superalloys will unlock superior mechanical, corrosion and technological properties, without subsequent thermomechanical treatments. Scientific outcomes are new physical metallurgy knowledge on the targeted selection of desirable interfaces via recrystallisation and coupled segregation-precipitation phenomena. Technological outcomes are processing maps for printing parts with customised microstructures. This will diminish anisotropy, residual stress and defects, benefitting defence, aerospace and energy applications, all vital to the Australian economy.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
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
Early Career Industry Fellowships - Grant ID: IE230100476
Funder
Australian Research Council
Funding Amount
$465,237.00
Summary
Development of rapid-response thermal batteries for the global market. In collaboration with Isothermix, this project aims to develop and commercialize cost-effective, rapid-response thermal batteries to meet the air conditioning peak demand of buildings. This project expects to generate new knowledge about the phase change materials which can be used to store thermal energy across a range of temperatures and the highly thermal conductive materials which can be used as a heat exchanger. Expected ....Development of rapid-response thermal batteries for the global market. In collaboration with Isothermix, this project aims to develop and commercialize cost-effective, rapid-response thermal batteries to meet the air conditioning peak demand of buildings. This project expects to generate new knowledge about the phase change materials which can be used to store thermal energy across a range of temperatures and the highly thermal conductive materials which can be used as a heat exchanger. Expected outcomes include the development of rapid response thermal batteries which can cool buildings across a range of temperatures and site conditions. This should provide significant benefits by reducing primary heating and cooling plant capacity and thereby our reliance on fossil fuels.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101344
Funder
Australian Research Council
Funding Amount
$437,854.00
Summary
Hierarchical Ta-Ti lattice materials by 3D printing and nanofabrication . This project aims to develop a novel approach to the manufacture of hierarchical Ta-Ti lattice materials with a fine nanoporous Ta surface through capitalizing on the advantages of metal 3D printing and a unique post nanofabrication process. This project expects to generate new fundamental knowledge in the design and manufacture of hierarchical metal lattice materials. Expected outcomes include a new advanced manufacturing ....Hierarchical Ta-Ti lattice materials by 3D printing and nanofabrication . This project aims to develop a novel approach to the manufacture of hierarchical Ta-Ti lattice materials with a fine nanoporous Ta surface through capitalizing on the advantages of metal 3D printing and a unique post nanofabrication process. This project expects to generate new fundamental knowledge in the design and manufacture of hierarchical metal lattice materials. Expected outcomes include a new advanced manufacturing method and a new class of highly biocompatible hierarchical Ta-Ti lattice materials. The former should benefit the Australian Manufacturing Industry for the manufacture of a variety of novel metal lattice materials or products while the latter has the potential for applications as implant materials.Read moreRead less
Nano-toughening of Conductive Composites with High Electrical Ductility. This project aims to develop a new technology to effectively toughen conductive thin films including metals and conductive polymers with significantly improved mechanical robustness for next-generation stretchable electronics. This new technique will tackle the major limitation of stretchable electronics propensity to abrupt electrical failure caused by plastic deformation and long channel cracks in conductive thin films of ....Nano-toughening of Conductive Composites with High Electrical Ductility. This project aims to develop a new technology to effectively toughen conductive thin films including metals and conductive polymers with significantly improved mechanical robustness for next-generation stretchable electronics. This new technique will tackle the major limitation of stretchable electronics propensity to abrupt electrical failure caused by plastic deformation and long channel cracks in conductive thin films of low yield strain and ductility. By overcoming the bottleneck issue of low stretchability and ductility of existing conductive thin film materials, it will be possible to significantly expand the design space of flexible and stretchable electronic devices.Read moreRead less
Empowering Wearable Smart Devices with 3D Printed Energy Storage. This project aims to design and develop functional nanomaterials and nanocomposites for high-performance wearable energy storage devices. A functional materials approach, together with precise control of device architecture through multi-materials additive manufacturing will be used to achieve maximum device performance. The expected outcomes include (i) fundamental understanding the structural-property relationships of materials ....Empowering Wearable Smart Devices with 3D Printed Energy Storage. This project aims to design and develop functional nanomaterials and nanocomposites for high-performance wearable energy storage devices. A functional materials approach, together with precise control of device architecture through multi-materials additive manufacturing will be used to achieve maximum device performance. The expected outcomes include (i) fundamental understanding the structural-property relationships of materials and devices and (ii) the establishment of the fundamental principles on the microfabrication of flexible energy storage devices. The project secures Australia’s leading position in materials chemistry and advanced manufacturing, bringing economic benefit through the commercialisation of wearable devices.Read moreRead less