Developing novel two-dimensional hybrid nanostructures for renewable energy. This project aims to develop novel two-dimensional (2D) hybrid nanostructures with new physical and chemical properties. This innovation intends to address the critical challenges of control functionalisation of 2D hybrid nanostructures: essential to understanding the potential of nanomaterials in key applications of energy generation. Expected outcomes include scalable technology to produce functional 2D nanomaterials ....Developing novel two-dimensional hybrid nanostructures for renewable energy. This project aims to develop novel two-dimensional (2D) hybrid nanostructures with new physical and chemical properties. This innovation intends to address the critical challenges of control functionalisation of 2D hybrid nanostructures: essential to understanding the potential of nanomaterials in key applications of energy generation. Expected outcomes include scalable technology to produce functional 2D nanomaterials and hybrid nanostructures to accelerate research to advanced materials and frontier material manufacturing technologies. This project will provide significant social and economic benefits to Australia in the growth of sectors in advanced materials, energy generation, and advanced manufacturing.Read moreRead less
Using extreme conditions to synthesise new materials. This project aims to synthesise useful materials from non-crystalline light element precursors. Boron, carbon and nitrogen are the hardest known solids, and their ability to form many kinds of chemical bonds offers opportunities for attractive new materials. This project will apply high pressures and temperatures to non-crystalline precursor materials to access previously unobtainable synthesis conditions. This project will create strong and ....Using extreme conditions to synthesise new materials. This project aims to synthesise useful materials from non-crystalline light element precursors. Boron, carbon and nitrogen are the hardest known solids, and their ability to form many kinds of chemical bonds offers opportunities for attractive new materials. This project will apply high pressures and temperatures to non-crystalline precursor materials to access previously unobtainable synthesis conditions. This project will create strong and hard materials with tuneable optical and electronic properties. The expected outcome is new light materials that emit and detect light in the far ultraviolet for biological imaging and tough materials with low friction needed for motors and regenerative technologies.Read moreRead less
Synthesis and Characterisation of Tracer-Functionalised Nanoparticles . This project aims to engineer nanomaterials by utilising gold nanochemistry and neural tracing capabilities of plant-based, nontoxic proteins. In a significant departure from current nanomaterials being developed, functionalising nanoparticles with the tracers enable them to undergo path-specific axonal retrograde transport, transneuronal transport, and anatomical tract flow to bypass the blood-brain barrier. Microfluidics w ....Synthesis and Characterisation of Tracer-Functionalised Nanoparticles . This project aims to engineer nanomaterials by utilising gold nanochemistry and neural tracing capabilities of plant-based, nontoxic proteins. In a significant departure from current nanomaterials being developed, functionalising nanoparticles with the tracers enable them to undergo path-specific axonal retrograde transport, transneuronal transport, and anatomical tract flow to bypass the blood-brain barrier. Microfluidics will be used to characterise the neuronal activities of the synthesised nanoconjugates of different sizes and compositions to understand their bio-interactions with axons, synapses, and neuromuscular junctions. The results will lead to a new class of functional nanomaterials as well as cell-based functional assays.Read moreRead less
Mass transport in high entropy alloys. This project aims to understand mass transport in high entropy alloys. Alloys of 5 to 13 components have technologically attractive mechanical properties. A knowledge of mass transport could control their stabilities and optimise their properties. This project will develop an atomistic theory and a phenomenological method for rapidly performing experiments, and experiment on two key high entropy alloys. The outcome of this research will be an in-depth under ....Mass transport in high entropy alloys. This project aims to understand mass transport in high entropy alloys. Alloys of 5 to 13 components have technologically attractive mechanical properties. A knowledge of mass transport could control their stabilities and optimise their properties. This project will develop an atomistic theory and a phenomenological method for rapidly performing experiments, and experiment on two key high entropy alloys. The outcome of this research will be an in-depth understanding of mass transport that is expected to fast-track these alloys to commercial uptake.Read moreRead less
Systems engineering approach to nanostructuring porous electrodes for compact capacitive energy storage. This project will develop a new systems engineering approach to fabricating porous yet densely packed electrodes with high ion-accessible surface area and low ion transport impedance. This will lead to new-generation compact electrochemical capacitive energy storage systems that can combine high energy density, fast charging/discharging rate and long cycle life. The success of this project wi ....Systems engineering approach to nanostructuring porous electrodes for compact capacitive energy storage. This project will develop a new systems engineering approach to fabricating porous yet densely packed electrodes with high ion-accessible surface area and low ion transport impedance. This will lead to new-generation compact electrochemical capacitive energy storage systems that can combine high energy density, fast charging/discharging rate and long cycle life. The success of this project will facilitate future large-scale adoption of renewable energy and many other new emerging technologies such as portable/wearable electronics, electric vehicles, and energy regeneration systems.Read moreRead less
Experimental mapping of electron densities in nano-structured materials. This project aims to map electrons in nano-structured materials using a new technique combining the latest solid-state theory with electron scattering experiments in one of the world’s most advanced electron microscopes. It is expected that by revealing the electronic structure of nano-scale features in bulk materials for the first time, their functions will become fully explainable. Aside from this new capability, other ....Experimental mapping of electron densities in nano-structured materials. This project aims to map electrons in nano-structured materials using a new technique combining the latest solid-state theory with electron scattering experiments in one of the world’s most advanced electron microscopes. It is expected that by revealing the electronic structure of nano-scale features in bulk materials for the first time, their functions will become fully explainable. Aside from this new capability, other expected outcomes include discovering how heat is converted into electricity in thermoelectric materials and how precipitates affect alloy strength. The benefits may include more informed materials design, more efficient thermoelectrics for sustainable energy technologies, and higher strength-to-weight ratio alloys.Read moreRead less
Ultra-high mobility Dirac semimetal nanostructures for solid state devices. This project aims to develop novel Dirac semimetal nanostructures and determine their structural and chemical characteristics to ultimately assemble high-performance devices. The growth of band-engineered nanostructures and understanding their evolution, fine structure and unique properties are key steps for developing high-performance nanostructure-based devices. The new knowledge and skills developed in this project wi ....Ultra-high mobility Dirac semimetal nanostructures for solid state devices. This project aims to develop novel Dirac semimetal nanostructures and determine their structural and chemical characteristics to ultimately assemble high-performance devices. The growth of band-engineered nanostructures and understanding their evolution, fine structure and unique properties are key steps for developing high-performance nanostructure-based devices. The new knowledge and skills developed in this project will greatly enhance the knowledge base of nanoscience and nanotechnology, and will have a significant impact on practical applications of nanostructure-based devices. This project will underpin the development of next-generation electronic nanomaterials that will enhance the long-term viability of Australia’s high-technology industries.Read moreRead less
Perovskite Materials: Exploring properties beyond solar cells. This project aims to explore functionalities of metal halide perovskite materials for sustainable solar energy conversion and storage, beyond the heavily studied perovskite solar cell application. The project intends to design toxic lead free/less perovskite materials for an integrated photoelectrochemical hydrogen production and solar rechargeable battery system. It will study the relations between material synthesis conditions, dev ....Perovskite Materials: Exploring properties beyond solar cells. This project aims to explore functionalities of metal halide perovskite materials for sustainable solar energy conversion and storage, beyond the heavily studied perovskite solar cell application. The project intends to design toxic lead free/less perovskite materials for an integrated photoelectrochemical hydrogen production and solar rechargeable battery system. It will study the relations between material synthesis conditions, device structure and performance of the photoelectrochemical system. Expected outcomes are low cost and more efficient solar-to-hydrogen conversion and solar energy storage devices, important for sustainable use of intermittent solar energy.Read moreRead less
Hot Topic: Quantum Design of Phononic Heat Filters. Heat management is critical to many technologies for sustainable energy, electronics, protective equipment and energy-efficient buildings. The phonon is the quantum particle representing a travelling vibration and is responsible for the transmission of heat in solids. This project will study the new mechanisms for phonon transport in solids modified with embedded nanoparticles, which operate as phononic filters. Neutron spectroscopy provides a ....Hot Topic: Quantum Design of Phononic Heat Filters. Heat management is critical to many technologies for sustainable energy, electronics, protective equipment and energy-efficient buildings. The phonon is the quantum particle representing a travelling vibration and is responsible for the transmission of heat in solids. This project will study the new mechanisms for phonon transport in solids modified with embedded nanoparticles, which operate as phononic filters. Neutron spectroscopy provides a tool to measure the phonon density of states which is critical for developing a mathematical model of thermal boundary resistance. This is expected to identify mechanisms for ultra-low thermal conductivity leading to potential applications in thermoelectric generators and heat-resistant materials.Read moreRead less
Layered and scrolled carbon materials for advancing energy storage systems. This project aims to reveal the structure–property relations in carbon electrodes through the design of model carbon systems that allow the simultaneous control of graphitic interlayer distance, ion diffusion pathway length, and surface functional group density. The project is expected to generate new knowledge on the charging mechanisms of micro-supercapacitors and sodium-ion batteries and technologies for emerging port ....Layered and scrolled carbon materials for advancing energy storage systems. This project aims to reveal the structure–property relations in carbon electrodes through the design of model carbon systems that allow the simultaneous control of graphitic interlayer distance, ion diffusion pathway length, and surface functional group density. The project is expected to generate new knowledge on the charging mechanisms of micro-supercapacitors and sodium-ion batteries and technologies for emerging portable electronics and renewable energy storage applications. The demonstration of high-performance and sustainable energy storage devices is anticipated. This will help to advance the prominence of Australia in the global renewable energy market and the move towards more sustainable economies and lifestyles.Read moreRead less