Discovery Early Career Researcher Award - Grant ID: DE220101190
Funder
Australian Research Council
Funding Amount
$418,292.00
Summary
Designing low-toxicity and stable perovskites for solar energy conversion. Efficient solar energy conversion systems can significantly promote sustainable and low carbon-emission economy. This project aims to rationally design low-toxic and stable metal halide perovskites for efficient solar hydrogen conversion. The key concept is to design stable lead-free metal halide perovskite semiconductors with superior photophysical properties for solar-driven valuable chemical production. Expected outcom ....Designing low-toxicity and stable perovskites for solar energy conversion. Efficient solar energy conversion systems can significantly promote sustainable and low carbon-emission economy. This project aims to rationally design low-toxic and stable metal halide perovskites for efficient solar hydrogen conversion. The key concept is to design stable lead-free metal halide perovskite semiconductors with superior photophysical properties for solar-driven valuable chemical production. Expected outcomes include new generation advanced materials and proof-of-concept technologies for efficient solar hydrogen generation. The successful completion of this project will benefit Australia by positioning the nation at the frontier of advanced functional materials and renewable energy supply technologies.Read moreRead less
Oxide-semiconductor epitaxy: towards next generation nanoelectronics. This project aims to integrate high quality functional oxide heterostructures with semiconductor platforms and address the fundamental obstacles in oxides for highly efficient and high-speed transistor applications by engineering their electronic band structures. The project aims to establish a bridge between the diverse electronic properties of oxides and the established semiconductor platform, and generate new devices and fu ....Oxide-semiconductor epitaxy: towards next generation nanoelectronics. This project aims to integrate high quality functional oxide heterostructures with semiconductor platforms and address the fundamental obstacles in oxides for highly efficient and high-speed transistor applications by engineering their electronic band structures. The project aims to establish a bridge between the diverse electronic properties of oxides and the established semiconductor platform, and generate new devices and functionalities. Expected outcomes include epitaxial functional oxides on Gallium arsenide with ultrahigh, room-temperature sheet electron mobility and a comprehensive understanding of its microscopic origin. This will fundamentally change the route toward novel transistors based on high speed and low energy oxide electronics.Read moreRead less
Perovskite Quantum Dots for Solar Hydrogen Generation. Sustainable hydrogen production is highly significant towards decarbonised economy. This project aims to develop new classes of organometal halide perovskite quantum dots (OHPQDs) for efficient photoelecrochemical hydrogen production. The key concept is to design toxic Lead free/less OHPQDs for use as stable photoelectrode materials in self-powered sunlight driven water splitting devices. Expected outcomes include new generation advanced mat ....Perovskite Quantum Dots for Solar Hydrogen Generation. Sustainable hydrogen production is highly significant towards decarbonised economy. This project aims to develop new classes of organometal halide perovskite quantum dots (OHPQDs) for efficient photoelecrochemical hydrogen production. The key concept is to design toxic Lead free/less OHPQDs for use as stable photoelectrode materials in self-powered sunlight driven water splitting devices. Expected outcomes include new generation advanced materials and revolutionary technologies for efficient solar hydrogen generation. The successful completion of this project will significantly benefit Australia by positioning the nation at the frontier of renewable hydrogen supply technologies. Read moreRead less
Design of new two-dimensional materials for lithium sulphur batteries. Design of new two-dimensional materials for lithium sulphur batteries. This project aims to develop classes of electrode material systems for high performance batteries. This project will design new hierarchical cathode composites for a high capacity lithium-sulphur battery with a long cycling life. It intends to improve energy density by confining active sulphur in conductive graphene and exfoliated titanium dioxide nanoshee ....Design of new two-dimensional materials for lithium sulphur batteries. Design of new two-dimensional materials for lithium sulphur batteries. This project aims to develop classes of electrode material systems for high performance batteries. This project will design new hierarchical cathode composites for a high capacity lithium-sulphur battery with a long cycling life. It intends to improve energy density by confining active sulphur in conductive graphene and exfoliated titanium dioxide nanosheets, and use a unique hybrid protecting layer to suppress cycling instability. This research is expected to establish the relationship between synthetic conditions, structure, and electrochemical performance.Read moreRead less
Bioinspired photo–iontronic membranes for smart neuron-mimicking systems. The project aims to address key fundamental questions about the development of bioinspired artificial nanochannels that can precisely mimic current signals and functionalities in neurons. This is expected to generate fundamental and applied knowledge in bioengineered photo–iontronic systems, harnessing a multidisciplinary approach to engineer materials with precisely tailored properties at the nanoscale for unprecedented d ....Bioinspired photo–iontronic membranes for smart neuron-mimicking systems. The project aims to address key fundamental questions about the development of bioinspired artificial nanochannels that can precisely mimic current signals and functionalities in neurons. This is expected to generate fundamental and applied knowledge in bioengineered photo–iontronic systems, harnessing a multidisciplinary approach to engineer materials with precisely tailored properties at the nanoscale for unprecedented dynamic control over ionic current through responsive, adaptable neuron-mimicking nanopores. Anticipated outcomes are advanced materials, integrated into smart architectures to overcome the limitations of solid-state systems for the next generation of integrated circuits, bio-interfacial sensors, and energy generators.Read moreRead less
Efficient photovoltaic-electrochemical water splitting for clean hydrogen. This project aims to develop a novel, low cost and high performance monolithic photovoltaic-electrochemical (PV-EC) device for clean hydrogen production. This device tailors and integrates low cost and high performance thin film and tandem photovoltaics for water splitting with the aim of achieving high solar to hydrogen conversion efficiency towards 20%. Earth abundant and stable catalysts will be developed in this proje ....Efficient photovoltaic-electrochemical water splitting for clean hydrogen. This project aims to develop a novel, low cost and high performance monolithic photovoltaic-electrochemical (PV-EC) device for clean hydrogen production. This device tailors and integrates low cost and high performance thin film and tandem photovoltaics for water splitting with the aim of achieving high solar to hydrogen conversion efficiency towards 20%. Earth abundant and stable catalysts will be developed in this project to replace noble based catalysts, as well as novel architectures for electrical contacting, feed-through and catalyst integration in PV-EC devices. These innovations offer high performance and the potential for device costs 2 to 3 orders of magnitude lower than recent world record photoelectrochemical devices. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101622
Funder
Australian Research Council
Funding Amount
$424,498.00
Summary
Synthesis of High-quality 2D Perovskites for Efficient Light Harvestings. This project aims to develop a library of novel and two-dimensional Ruddlesden−Popper phases layered perovskites with controlled architecture and tunable bandgaps for high-performance energy harvesting applications. The as-synthesized perovskites are highly crystalline and sandwiched with staggered organic and inorganic layers, which are compatible with layer-by-layer manner to build vertical heterostructure, satisfying t ....Synthesis of High-quality 2D Perovskites for Efficient Light Harvestings. This project aims to develop a library of novel and two-dimensional Ruddlesden−Popper phases layered perovskites with controlled architecture and tunable bandgaps for high-performance energy harvesting applications. The as-synthesized perovskites are highly crystalline and sandwiched with staggered organic and inorganic layers, which are compatible with layer-by-layer manner to build vertical heterostructure, satisfying the premise of a solar cell with both high power conversion efficiency and low-cost. Apart from springing out a series of high impact publications and patents, a few of these demonstrations have a great potential to be substituted for fossil fuels which will help address clean energy generation and environmental problems. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100435
Funder
Australian Research Council
Funding Amount
$383,982.00
Summary
Photonic Crystal Sensors for Intelligent Packaging. This project aims to synthesize and investigate the properties of optical sensors composed of oriented assembled, high-flexible metal-organic-framework-based photonic crystals. This project is expected to generate new knowledge in the area of oriented self-assembly and elucidate the relationship between the optical properties of photonic crystal optical sensors and the orientation, flexibility and functionalisation of metal-organic frameworks. ....Photonic Crystal Sensors for Intelligent Packaging. This project aims to synthesize and investigate the properties of optical sensors composed of oriented assembled, high-flexible metal-organic-framework-based photonic crystals. This project is expected to generate new knowledge in the area of oriented self-assembly and elucidate the relationship between the optical properties of photonic crystal optical sensors and the orientation, flexibility and functionalisation of metal-organic frameworks. Expected outcomes of this project include novel oriented assembly methods and a series of optical sensing devices for various detection scenarios. This research will provide significant benefits on environmental protection, sustainable development, food safety and human health.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101120
Funder
Australian Research Council
Funding Amount
$419,904.00
Summary
2D Janus Nanoparticle Superlattice Sheets. The project aims to fabricate novel 2D free-standing Janus superlattices by developing a new ligand-symmetry breaking strategy. The proposed approach expects to generate new knowledge in the area of self-assembly and the new class of 2D plasmonic nanomaterials. Expected outcomes of this project include the fabrication of a series of 2D Janus superlattices that are difficult or impossible to achieve in traditional methods, investigate their functional-pr ....2D Janus Nanoparticle Superlattice Sheets. The project aims to fabricate novel 2D free-standing Janus superlattices by developing a new ligand-symmetry breaking strategy. The proposed approach expects to generate new knowledge in the area of self-assembly and the new class of 2D plasmonic nanomaterials. Expected outcomes of this project include the fabrication of a series of 2D Janus superlattices that are difficult or impossible to achieve in traditional methods, investigate their functional-properties relationship and further apply them into dual-functional plasmonic-catalyst/sensor/filtration applications. This should provide significant benefits, such as developing new design principles for self-assembly and advance Australian expertise in the field of functional nanomaterials.Read moreRead less
Scalable atom-thin materials for monolithic electronics & optoelectronics. This project aims to understand large-area growth mechanisms and create practical, controllable doping methodologies for developing manufacturing-compatible tunable materials to overcome technological challenges presented by silicon. The project expects to generate new understanding of physico-chemical mechanisms that govern the optical and electrical properties of an emerging class of materials only few-atoms thick that ....Scalable atom-thin materials for monolithic electronics & optoelectronics. This project aims to understand large-area growth mechanisms and create practical, controllable doping methodologies for developing manufacturing-compatible tunable materials to overcome technological challenges presented by silicon. The project expects to generate new understanding of physico-chemical mechanisms that govern the optical and electrical properties of an emerging class of materials only few-atoms thick that offer unprecedented opportunities. This is expected to establish a suite of atomically-thin materials that will be deployed in miniaturised, high-density electronics and optoelectronics of which proof-of-concept functional devices are proposed to be demonstrated. These will be leveraged to explore industry partnerships.Read moreRead less