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Hot carrier cooling mechanisms in nano structures. This project aims to systematically investigate possible mechanisms of hot carrier cooling in nano structures and to identify the most dominant mechanisms. These are important for efficient hot carrier solar cells and thermoelectrics. This project will develop new physics to understand hot carrier dynamics in nano structures. This project is expected to result in photovoltaic systems with a lower balance of system and levelised cost of electrici ....Hot carrier cooling mechanisms in nano structures. This project aims to systematically investigate possible mechanisms of hot carrier cooling in nano structures and to identify the most dominant mechanisms. These are important for efficient hot carrier solar cells and thermoelectrics. This project will develop new physics to understand hot carrier dynamics in nano structures. This project is expected to result in photovoltaic systems with a lower balance of system and levelised cost of electricity compared to conventional technologies. This should boost solar industry, create green jobs and reduce greenhouse gas emissions.Read moreRead less
Nanofabrication of Metamaterials for Next Generation Optical Devices. The dream of invisibility cloaks dates back to ancient times but recent advances in nanotechnology have made this a reality through the use of metamaterials. Metamaterials are artificially-made materials that have optical properties not found in nature. This field is still in its infancy and significant challenges remain and need to be solved before practical applications can be realised. This project builds on Australia’s str ....Nanofabrication of Metamaterials for Next Generation Optical Devices. The dream of invisibility cloaks dates back to ancient times but recent advances in nanotechnology have made this a reality through the use of metamaterials. Metamaterials are artificially-made materials that have optical properties not found in nature. This field is still in its infancy and significant challenges remain and need to be solved before practical applications can be realised. This project builds on Australia’s strategic investment in nanofabrication capabilities to fabricate functional metamaterials and uncover the underlying physical phenomena. It will revolutionise the field of nanophotonics for a variety of novel applications ranging from defence, renewable energy, imaging, sensing to optical communications.Read moreRead less
Solar rechargeable Zinc-Bromine Flow Batteries. This project aims to develop a new solar rechargeable Zinc-Bromine flow battery for better utilization of the abundant yet intermittently available sunlight. The key design is to create a solar-driven photoelectrochemical process to convert the discharged electrode materials back to their charged states and realise the direct storage of solar energy. Expected outcomes include new solar driven rechargeable technology and photoelectrode materials, as ....Solar rechargeable Zinc-Bromine Flow Batteries. This project aims to develop a new solar rechargeable Zinc-Bromine flow battery for better utilization of the abundant yet intermittently available sunlight. The key design is to create a solar-driven photoelectrochemical process to convert the discharged electrode materials back to their charged states and realise the direct storage of solar energy. Expected outcomes include new solar driven rechargeable technology and photoelectrode materials, as well as new knowledge generated from collaborations across materials science, photoelectrochemistry and nanotechnology disciplines. Further advances in functional materials for solar energy storage will assist in addressing the global energy shortage and mitigating environmental pollution.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
Nanostructuring and nanocharacterisation of organic semiconductor devices. This research project will utilise new approaches to pattern organic solar cells on the nanoscale to realise improved efficiencies and improved understanding of device operation. It will also develop soft x-ray techniques to probe the nanostructure of organic semiconductor films with increased chemical and interfacial specificity.
van der Waals epitaxy for advanced and flexible optoelectronics. This project aims to investigate the growth of compound semiconductors directly on two-dimensional material templates, via the so-called van der Waals epitaxy. Two-dimensional materials combined with compound semiconductors as optoelectronic materials can have many uses. This project expects to design flexible solar cells, which could be integrated with fabrics or building products, and lasers that need small drive currents. It wil ....van der Waals epitaxy for advanced and flexible optoelectronics. This project aims to investigate the growth of compound semiconductors directly on two-dimensional material templates, via the so-called van der Waals epitaxy. Two-dimensional materials combined with compound semiconductors as optoelectronic materials can have many uses. This project expects to design flexible solar cells, which could be integrated with fabrics or building products, and lasers that need small drive currents. It will use the Anderson localisation effect, a photon management concept, to control the interaction between photons and material and improve device efficiencies.Read moreRead less
Indoor Photovoltaics Enabled by Wide-Bandgap Perovskite Quantum Dots. This project aims to develop a high-efficiency indoor photovoltaic (PV) technology to provide reliable low-cost power in the multi-billion dollar “Internet of Things” (IoT) market. There are currently no devices that meet the requirements for maximum operating efficiency under indoor illumination. We propose to solve this problem by fabricating PV cells using colloidal perovskite quantum dots that offer class-leading stability ....Indoor Photovoltaics Enabled by Wide-Bandgap Perovskite Quantum Dots. This project aims to develop a high-efficiency indoor photovoltaic (PV) technology to provide reliable low-cost power in the multi-billion dollar “Internet of Things” (IoT) market. There are currently no devices that meet the requirements for maximum operating efficiency under indoor illumination. We propose to solve this problem by fabricating PV cells using colloidal perovskite quantum dots that offer class-leading stability and band gap tunability across the required range, enabled by quantum confinement. The outcome is the development of integrated self-powered IoT devices potentially impacting Advanced Manufacturing growth in Energy, Cyber Security, Food and Agribusiness, as all of these will ultimately rely on networked smart devices.Read moreRead less
III-V semiconductor nanowire solar cells without p-n junctions. This project proposes a new class of nanowire solar cells that do not rely on conventional electrical (p-n) junction for photo-generated charge carrier separation. Instead the band structure of the semiconductors is engineered to form a misalignment which leads to the spatial separation of carriers. This approach is expected to fundamentally change the design of solar cells, eliminating the technologically challenging need for formi ....III-V semiconductor nanowire solar cells without p-n junctions. This project proposes a new class of nanowire solar cells that do not rely on conventional electrical (p-n) junction for photo-generated charge carrier separation. Instead the band structure of the semiconductors is engineered to form a misalignment which leads to the spatial separation of carriers. This approach is expected to fundamentally change the design of solar cells, eliminating the technologically challenging need for forming good electrical junctions, while retaining all advantages inherent to III-V semiconductor nanowire solar cells. More importantly, the device concept proposed is expected to have implications for a wider class of solar cells based on exotic/novel materials or nanostructures where achieving both n- and p-doping may be challenging.Read moreRead less
Towards high performance compound semiconductor nanowire array solar cells. Semiconductor nanowires have great potential for photovoltaic applications due to their unique structural, electrical and optical properties. This project aims to establish a new research program to integrate highly sophisticated theoretical modelling, material growth and nanofabrication capabilities to develop high performance III-V compound semiconductor nanowire array solar cells. New concepts, strategies and technolo ....Towards high performance compound semiconductor nanowire array solar cells. Semiconductor nanowires have great potential for photovoltaic applications due to their unique structural, electrical and optical properties. This project aims to establish a new research program to integrate highly sophisticated theoretical modelling, material growth and nanofabrication capabilities to develop high performance III-V compound semiconductor nanowire array solar cells. New concepts, strategies and technologies developed by this project will not only advance the fundamental understanding of many intriguing physics in nanowire materials and devices, but also pave the way towards high efficiency photovoltaics to address the world’s energy-related issues. Read moreRead less
III-V Semiconductor Nanowire Solar Cells. III-V semiconductors, proven as excellent photovoltaic materials, combined with unique properties of nanowires will be investigated as new materials for third generation high efficiency solar cells. It will lead to fundamental understanding of photovoltaic mechanisms in nanowires and demonstration of nanowire solar cells for future applications.