A new photoelectrochemical system for solar hydrogen and electricity. This project aims to develop a new integrated photoelectrochemical (PEC) system for converting solar energy into hydrogen and electricity simultaneously. The key concept is to design innovative advanced materials which will be integrated into PEC devices with capacitor function for both solar fuel production and electricity storage. This project expects to generate new knowledge in understanding the fundamental mechanism of de ....A new photoelectrochemical system for solar hydrogen and electricity. This project aims to develop a new integrated photoelectrochemical (PEC) system for converting solar energy into hydrogen and electricity simultaneously. The key concept is to design innovative advanced materials which will be integrated into PEC devices with capacitor function for both solar fuel production and electricity storage. This project expects to generate new knowledge in understanding the fundamental mechanism of developing functional materials for more efficient solar energy conversion and storage. Expected outcomes include prototypes of the next generation advanced materials and technologies for sustainable energy utilisation systems for converting solar energy into hydrogen and electricity.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
A New Photocatalytic System for Solar-to-Chemical Energy Conversion. The expected outcomes of this program are a new class of photocatalyst systems for converting waste products into valuable chemicals using solar energy. Using advanced materials and photocatalysis, the project aims to develop a new class of bi-functional photoelectrochemical (PEC) systems for application in waste brine treatment and valuable chemical generation. The key concept lies in the innovative design of layered semicondu ....A New Photocatalytic System for Solar-to-Chemical Energy Conversion. The expected outcomes of this program are a new class of photocatalyst systems for converting waste products into valuable chemicals using solar energy. Using advanced materials and photocatalysis, the project aims to develop a new class of bi-functional photoelectrochemical (PEC) systems for application in waste brine treatment and valuable chemical generation. The key concept lies in the innovative design of layered semiconductors as efficient and stable photocatalysts and their integration into PEC reaction systems for simultaneous solar hydrogen and valuable chemicals (eg bromine) generation from brine. The project aims to advance fundamental understanding of the photocatalytic water-splitting concept to other waste product splitting.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180101253
Funder
Australian Research Council
Funding Amount
$367,646.00
Summary
Perovskite photovoltaic-assisted energy conversion system using wastewater. This project aims to explore the potential of a solar-driven electrochemical system to simultaneously generate hydrogen and electricity by utilising wastewater as a fuel. The key concept of this system is integrating high efficiency perovskite solar cells as a high voltage supplier, with the electrochemical system to accelerate solar-to-hydrogen conversion and oxygen reduction for solar-to-electricity conversion during o ....Perovskite photovoltaic-assisted energy conversion system using wastewater. This project aims to explore the potential of a solar-driven electrochemical system to simultaneously generate hydrogen and electricity by utilising wastewater as a fuel. The key concept of this system is integrating high efficiency perovskite solar cells as a high voltage supplier, with the electrochemical system to accelerate solar-to-hydrogen conversion and oxygen reduction for solar-to-electricity conversion during oxidisation of organic fuels in wastewater. This project expects to open up an independent and transportable power grid-free electrochemical system to address energy and water utilisation issues, especially for remote and Indigenous areas in Australia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100126
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
An integrated kinetic measurement system enabling efficient solar energy conversion. This measurement facility will underpin advances in the fundamental understanding of new semiconducting materials for high efficiency light-driven energy conversion systems. The outcomes of the research at the facility will lead to significant economic and environmental benefits for many industries, such as low cost solar cells and water purifications.
Metal-support interactions: single atoms Vs nanoclusters. This project aims to fundamentally understand the catalytic mechanism at an atomic level through metal-metal and metal-metal/support interactions. The optimised configuration of active sites for a specific reaction is consequently identified, providing the design principles of novel catalysts. The precisely control of synthesis for such active sites and assembly of the target active sites into a catalyst will deliver a completely new meth ....Metal-support interactions: single atoms Vs nanoclusters. This project aims to fundamentally understand the catalytic mechanism at an atomic level through metal-metal and metal-metal/support interactions. The optimised configuration of active sites for a specific reaction is consequently identified, providing the design principles of novel catalysts. The precisely control of synthesis for such active sites and assembly of the target active sites into a catalyst will deliver a completely new methodology for catalyst development. The expected outcomes from this project include new science and knowledge of Chemistry, new design philosophy and strategies for catalysts, and the highly efficient catalysts for electrocatalytic reactions, benefiting Australian renewable energy research and industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100129
Funder
Australian Research Council
Funding Amount
$425,200.00
Summary
Atomic layer nanofabrication system for multi-functional applications. This project aims to establish a multifunctional atomic layer nanofabrication facility in Sydney with the capacity to provide services nation-wide. The facility has powerful capabilities to produce mono-atom thin films, nanosize powders and two-dimensional nanostructures of a variety of materials, including elemental metals, metal oxides, metal nitrides, metal sulfides, metal-metal compounds, and polymers. This will significa ....Atomic layer nanofabrication system for multi-functional applications. This project aims to establish a multifunctional atomic layer nanofabrication facility in Sydney with the capacity to provide services nation-wide. The facility has powerful capabilities to produce mono-atom thin films, nanosize powders and two-dimensional nanostructures of a variety of materials, including elemental metals, metal oxides, metal nitrides, metal sulfides, metal-metal compounds, and polymers. This will significantly enhance Australian research and industrial activities in the areas of renewable energy production and storage, microelectronics, chemical and bio-sensors, protective coatings, flexible electronic devices, and catalysis.Read moreRead less
Well-designed Metal Oxide Semiconductors for Photocatalytic Water Splitting. The project seeks to provide new insights into the effects that structure and composition of catalyst materials have on photocatalytic properties, to tackle the bottlenecks inhibiting the commercialisation of water-splitting technology. The main objective of this project is to strategically design and synthesise highly efficient photo-harvesting mesostructural materials (multi-shelled hollow microspheres) and use them f ....Well-designed Metal Oxide Semiconductors for Photocatalytic Water Splitting. The project seeks to provide new insights into the effects that structure and composition of catalyst materials have on photocatalytic properties, to tackle the bottlenecks inhibiting the commercialisation of water-splitting technology. The main objective of this project is to strategically design and synthesise highly efficient photo-harvesting mesostructural materials (multi-shelled hollow microspheres) and use them for efficient photocatalytic water splitting. Based on an understanding of photoharvesting materials and the current challenges that plague water-splitting reactions, the project plans to use state-of-the-art materials synthesis and theoretical calculations to develop next-generation photo-harvesting materials for water-splitting systems.Read moreRead less
High performance sustainable carbon fibres from Australian spinifex grass. Spinifex grasses cover approximately 30 per cent of our Australian continent, in the driest regions. It has been found that, presumably because of this harsh environment, they are uniquely easy to break down into ultra-long, thin cellulose nanofibrils. Through the use of novel catalysts and advanced processing techniques, this project aims to take advantage of this trait to deliver the cost-effective production of high st ....High performance sustainable carbon fibres from Australian spinifex grass. Spinifex grasses cover approximately 30 per cent of our Australian continent, in the driest regions. It has been found that, presumably because of this harsh environment, they are uniquely easy to break down into ultra-long, thin cellulose nanofibrils. Through the use of novel catalysts and advanced processing techniques, this project aims to take advantage of this trait to deliver the cost-effective production of high strength, sustainable carbon fibres from nanocellulose. It is expected that the use of the world's first university based research facility capable of producing high quality carbon fibre (CarbonNexus) will ensure the product is industrially relevant, with real potential to capture a share of the $14 billion carbon-fibre-composite market.Read moreRead less