Aligning and Chaining Carbon Nanofillers in Fibre Composites: Synergistically Improving Damage Tolerance and Diagnosis. Recent studies reveal that alternating electric or magnetic fields can rotate conductive nanofillers in polymers. This project aims to advance a new concept of aligning nano-scale reinforcements (for example, graphene nano-sheets and carbon nanofibres) along the thickness direction of composite materials. The alignment of nano-sized reinforcement will address the perennial prob ....Aligning and Chaining Carbon Nanofillers in Fibre Composites: Synergistically Improving Damage Tolerance and Diagnosis. Recent studies reveal that alternating electric or magnetic fields can rotate conductive nanofillers in polymers. This project aims to advance a new concept of aligning nano-scale reinforcements (for example, graphene nano-sheets and carbon nanofibres) along the thickness direction of composite materials. The alignment of nano-sized reinforcement will address the perennial problem of through-thickness weaknesses of fibre-reinforced composites and, at the same time, improve the electrical conductivity of composites. The synergistic improvements in the mechanical and electrical properties will improve damage tolerance and diagnosis of composites, thus expanding their applications in transport and civil construction to help reduce carbon dioxide emission.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101795
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
Exceptional properties by design – NiTi vision. The fundamental leaps in new technologies occur with improvements in the materials with which they are made. Until recently high performance metallic composite design had hit a 20 year blockage in nanocomposite design. The solution, a Nickel, Titanium and Niobium (NiTi-Nb) nanowire composite has been heralded as an era of new possibilities in materials design. This project aims to advance high performance metallic composite design by investigating ....Exceptional properties by design – NiTi vision. The fundamental leaps in new technologies occur with improvements in the materials with which they are made. Until recently high performance metallic composite design had hit a 20 year blockage in nanocomposite design. The solution, a Nickel, Titanium and Niobium (NiTi-Nb) nanowire composite has been heralded as an era of new possibilities in materials design. This project aims to advance high performance metallic composite design by investigating the mechanisms of exceptionally large elastic strains achieved in nanowires embedded in a phase-transforming metallic matrix (i.e. NiTi). An understanding of this high performance nanocomposite design has broad application in medicine and engineering.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL190100139
Funder
Australian Research Council
Funding Amount
$3,185,850.00
Summary
New Artificial Leaf for Efficient Solar Fuel Production . The Fellowship aims to develop next-generation materials that harness solar energy to produce valuable fuels and chemicals from water and carbon dioxide, replacing fossil fuels. The program will design new semiconductor materials to revolutionise solar-to-fuel technologies that currently have very low efficiency. The expected outcomes include innovative systems such as wireless artificial leaves that mimic natural photosynthesis for effic ....New Artificial Leaf for Efficient Solar Fuel Production . The Fellowship aims to develop next-generation materials that harness solar energy to produce valuable fuels and chemicals from water and carbon dioxide, replacing fossil fuels. The program will design new semiconductor materials to revolutionise solar-to-fuel technologies that currently have very low efficiency. The expected outcomes include innovative systems such as wireless artificial leaves that mimic natural photosynthesis for efficient hydrocarbon production, carbon dioxide reduction, and water purification. The expected benefits include next-generation solar fuel and chemical generation technologies, and research capabilities to position Australia as a global leader in the transition to a decarbonised economy.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL180100053
Funder
Australian Research Council
Funding Amount
$3,162,000.00
Summary
Re-discovering liquid metals from core to surface. This project aims to investigate and make new discoveries on the unique properties of liquid metals. Liquid metals have traditionally been used in mining, for switches, barometers, heat transfer units, and coolers and heaters. However, recent discoveries have indicated that liquid metals have untapped potential in applications for creating systems with extraordinary physical and chemical properties. This project will expand our knowledge of liqu ....Re-discovering liquid metals from core to surface. This project aims to investigate and make new discoveries on the unique properties of liquid metals. Liquid metals have traditionally been used in mining, for switches, barometers, heat transfer units, and coolers and heaters. However, recent discoveries have indicated that liquid metals have untapped potential in applications for creating systems with extraordinary physical and chemical properties. This project will expand our knowledge of liquid metals by exploring liquid metals as electron rich solvents and investigating new properties to develop future applications in electronics, optics, catalysts, thermal devices and bio systems.Read moreRead less
Electronic coupling and nanoscale engineering of two-dimensional nanojunctions. This project aims to improve the design of photovoltaic, energy storage, and nanocatalytic devices by using quantum-size tuning, orientation control, strain engineering, and surface modification to manipulate the electronic coupling and charge transfer of two-dimensional nanojunctions. The limitations of and potential environmental damage from fossil-fuel-based energy resources have increased interest in renewable en ....Electronic coupling and nanoscale engineering of two-dimensional nanojunctions. This project aims to improve the design of photovoltaic, energy storage, and nanocatalytic devices by using quantum-size tuning, orientation control, strain engineering, and surface modification to manipulate the electronic coupling and charge transfer of two-dimensional nanojunctions. The limitations of and potential environmental damage from fossil-fuel-based energy resources have increased interest in renewable energy research. The expected outcomes are electron-scale understanding of the tuneable functionalisation of two-dimensional nanojunctions and the design of low-cost and high-efficiency renewable energy devices.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC160100032
Funder
Australian Research Council
Funding Amount
$3,024,379.00
Summary
ARC Training Centre in Lightweight Automotive Structures. ARC Training Centre in Lightweight Automotive Structures. This training centre aims to train a cohort of industry-focused researchers and to develop new lightweighting technologies, which are key to reducing carbon dioxide (CO2 emissions in transportation. In partnership with domestic and international companies and universities, this centre intends to develop new lightweight materials, advanced manufacturing processes, energy storage des ....ARC Training Centre in Lightweight Automotive Structures. ARC Training Centre in Lightweight Automotive Structures. This training centre aims to train a cohort of industry-focused researchers and to develop new lightweighting technologies, which are key to reducing carbon dioxide (CO2 emissions in transportation. In partnership with domestic and international companies and universities, this centre intends to develop new lightweight materials, advanced manufacturing processes, energy storage designs, and rapid non-destructive evaluation techniques. The intended outcome is to accelerate the transformation of Australia's automotive industry—now facing unprecedented structural adjustment—from vehicle production to export of design and engineering services, high-value products, and novel technology solutions.Read moreRead less
Multifunctional 2D materials for sustainable energy applications. This project seeks to explore the great potential of novel graphene-like two dimensional (2-D) materials for energy applications. 2-D materials, which possess atomic or molecular thickness and infinite planar lengths, are regarded as a building block for many applications due to their unique nanostructures, electronic and mechanical properties. This project is focused on the design and exploration of layered two-dimensional artifi ....Multifunctional 2D materials for sustainable energy applications. This project seeks to explore the great potential of novel graphene-like two dimensional (2-D) materials for energy applications. 2-D materials, which possess atomic or molecular thickness and infinite planar lengths, are regarded as a building block for many applications due to their unique nanostructures, electronic and mechanical properties. This project is focused on the design and exploration of layered two-dimensional artificial graphene and graphene analogues with ‘on-demand’ properties to exploit advanced energy applications. There is now a pressing need to integrate graphene sheets into multidimensional and multifunctional systems with spatially well-defined configurations, and integrated systems with a controllable structure and predictable performance. Project outcomes may lead to next-generation devices in energy storage and other applications.Read moreRead less
Multi-functional graphene interleaves in multi-scale carbon fibre reinforced composites. This research project will lead to the development of a new class of multi-functional composites with improved mechanical/fracture performance and in-built health monitoring capability. The new composite systems will revolutionise the design of composite structures for the new generation aerospace vehicles.
Discovery Early Career Researcher Award - Grant ID: DE220100656
Funder
Australian Research Council
Funding Amount
$406,742.00
Summary
Aqueous-based potassium ion batteries for scalable energy storage. The aim of this project is to develop aqueous-based potassium ion batteries for new energy storage applications that currently have barely been studied. This project will design novel cathode/anode materials and electrolytes to significantly advance knowledge in this new technology. The expected outcomes include high-performance aqueous-based potassium ion batteries, while new fundamental knowledge of the reaction mechanisms will ....Aqueous-based potassium ion batteries for scalable energy storage. The aim of this project is to develop aqueous-based potassium ion batteries for new energy storage applications that currently have barely been studied. This project will design novel cathode/anode materials and electrolytes to significantly advance knowledge in this new technology. The expected outcomes include high-performance aqueous-based potassium ion batteries, while new fundamental knowledge of the reaction mechanisms will enhance our research capabilities to position Australia as a leader in potassium ion storage.Read moreRead less
Accelerated discovery of solar hydrogen photocatalysts. Solar photocatalysis is recognised as an environmentally sustainable process for production of Hydrogen. The adaptation of sophisticated machine learning to innovate solar photocatalysis hydrogen evolution is under question. We aim to harvest scientific principles and integrate with robust protocols to obtain a machine-augmented rational workflow guiding and accelerating discovery of optimal catalysts for solar hydrogen production – solving ....Accelerated discovery of solar hydrogen photocatalysts. Solar photocatalysis is recognised as an environmentally sustainable process for production of Hydrogen. The adaptation of sophisticated machine learning to innovate solar photocatalysis hydrogen evolution is under question. We aim to harvest scientific principles and integrate with robust protocols to obtain a machine-augmented rational workflow guiding and accelerating discovery of optimal catalysts for solar hydrogen production – solving a major bottleneck. The project will contribute largely to Australia’s renewable energy sector; fundamental knowledge-based cognitive photocatalysis platform would be conveniently scalable and transferable to mechanistically relevant processes, such as ammonia synthesis and greenhouse gas reduction.Read moreRead less