Concepts towards the next generation of dye-sensitised solar cells: tandem and plasmonic solar cells. This project aims at exploring the feasibility of novel device concepts to enhance the performance of dye-sensitised solar cells. These concepts include tandem solar cells as well as novel energy relay systems based on the ability of nanoparticles to effectively act as antenna systems that can funnel energy towards a sensitising dye molecule.
Advanced metallisation for III-V Photovoltaic Solar Power Systems. This project aims to augment the overall electrical efficiency of concentrator photovoltaic solar systems that provide large-scale generation of cheap, clean electricity. Existing concentrator solar cells are highly efficient (>40%) but their performance is hampered by thick front-metal contacts that shade the cell. The project is expected to develop a new concentrator solar cell metalisation and insulation technology. The benefi ....Advanced metallisation for III-V Photovoltaic Solar Power Systems. This project aims to augment the overall electrical efficiency of concentrator photovoltaic solar systems that provide large-scale generation of cheap, clean electricity. Existing concentrator solar cells are highly efficient (>40%) but their performance is hampered by thick front-metal contacts that shade the cell. The project is expected to develop a new concentrator solar cell metalisation and insulation technology. The benefit of the project will be a direct increase in the system efficiency and simplified manufacturing of the concentrator solar receiver, which in turn reduces the cost of the concentrator power plant constructed by our Australian project partner RayGen Resources Pty Ltd.Read moreRead less
A new defect-control approach for mismatched heteroepitaxy semiconductors. This project aims to develop a new defect-control approach for silicon-germanium heteroepitaxial semiconductor systems to provide a route for high-throughput, low-cost, high-efficiency silicon tandem solar cells. Mismatched heteroepitaxy of semiconductors is of considerable interest for fabricating novel devices. However, the use of highly-mismatched heteroepitaxial semiconductors has been limited due to the high densitie ....A new defect-control approach for mismatched heteroepitaxy semiconductors. This project aims to develop a new defect-control approach for silicon-germanium heteroepitaxial semiconductor systems to provide a route for high-throughput, low-cost, high-efficiency silicon tandem solar cells. Mismatched heteroepitaxy of semiconductors is of considerable interest for fabricating novel devices. However, the use of highly-mismatched heteroepitaxial semiconductors has been limited due to the high densities of crystal defects which degrade the performance of both majority and minority carrier devices. This project aims to develop a new defect-control approach for heteroepitaxial semiconductors by continuous wavelength diode laser processing. With heteroepitaxial silicon-germanium as an example, the project will investigate the mechanism underlying defect-cleaning, optimised designs for best performance, and designs for high-efficiency tandem solar cells.Read moreRead less
Kesterite solar cell coated architectural stainless steel. This project aims to develop cost-effective, high-performance kesterite architectural stainless steel coated with solar cells for application in roofing, skin and facades of smart buildings. The project will integrate expertise in producing kesterite solar cells with expertise in manufacturing new steel to eliminate toxic, scarce materials and high-cost processes employed in conventional solar-driven steel. The initial target of the proj ....Kesterite solar cell coated architectural stainless steel. This project aims to develop cost-effective, high-performance kesterite architectural stainless steel coated with solar cells for application in roofing, skin and facades of smart buildings. The project will integrate expertise in producing kesterite solar cells with expertise in manufacturing new steel to eliminate toxic, scarce materials and high-cost processes employed in conventional solar-driven steel. The initial target of the project would be to increase kesterite cell efficiency to beyond 10 per cent, and ultimately beyond 17 per cent, but still at a low cost.Read moreRead less
Photonic crystals at visible wavelengths. Three dimensional sculptured nano-structures made at a very high spatial resolution will open way to control light emission, propagation, and transmission at the visible wavelengths. Optically thin and transparent solar cells will be able to harvest light using structures.
Stable Non-toxic Organic-inorganic Halide Perovskite Solar Cells. The project aims to develop next-generation organic-inorganic halide solar cells which are stable and non-toxic. Although rapid progress has been made in the emerging perovskite solar cell technology, it currently relies on lead as a key perovskite component. The elimination of lead from organic-inorganic halide perovskite solar cells would greatly increase their acceptance as an alternative thin film photovoltaic solution because ....Stable Non-toxic Organic-inorganic Halide Perovskite Solar Cells. The project aims to develop next-generation organic-inorganic halide solar cells which are stable and non-toxic. Although rapid progress has been made in the emerging perovskite solar cell technology, it currently relies on lead as a key perovskite component. The elimination of lead from organic-inorganic halide perovskite solar cells would greatly increase their acceptance as an alternative thin film photovoltaic solution because of their low cost and non-toxic nature. The dearth of lead-free perovskite solar cell demonstrations and the relatively low conversion efficiencies demonstrated understate their potential. This project plans to improve understanding of their photovoltaic enabling attributes by characterising and modelling their optical and electrical properties. It then plans to apply new fabrication methods to develop lead-free solar devices.Read moreRead less
High-performance smart solar powered on-chip capacitive energy storage. High performance and environmentally friendly on-chip power system is the key bottleneck issue limiting the further performance improvement and miniaturisation of ever-increasing portable optoelectronic devices. Building on previous work, including recent breakthroughs of on-chip photonic devices in patterned graphene oxide thin film and the record-breaking nanophotonics solar cells, the project aims to investigate a new con ....High-performance smart solar powered on-chip capacitive energy storage. High performance and environmentally friendly on-chip power system is the key bottleneck issue limiting the further performance improvement and miniaturisation of ever-increasing portable optoelectronic devices. Building on previous work, including recent breakthroughs of on-chip photonic devices in patterned graphene oxide thin film and the record-breaking nanophotonics solar cells, the project aims to investigate a new concept of super-resolution direct laser printing and simultaneous dopant activation of graphene oxide thin films. It is expected that the conceptually new development of the functional graphene oxide film patterning will allow for smart solar-powered on-chip power systems that outperform the state-of-the-art pollution generating batteries.Read moreRead less
Towards ab initio molecular dynamics simulations of proton and electron transfer processes. Electrochemical technologies seek design capabilities to enable the discovery of novel electrolytes with valuable properties. This project will develop new advanced computational methods to understand electron and proton transfer in electrolytes and thereby allow us to enhance performance of electrochemical devices and control metal deposition.
Discovery Early Career Researcher Award - Grant ID: DE190101501
Funder
Australian Research Council
Funding Amount
$408,000.00
Summary
Printed back electrodes enabling low-cost perovskite solar cells. This project aims to address back electrode material, a bottleneck functional material in state-of-the-art perovskite solar cells (PSCs). By engineering printable and conductive materials based on carbon and gold nanowires, the project expects to enable highly-efficient and scalable PSCs while reducing cost of materials and production. These expected outcomes are to be implemented in PSCs and their impact rigorously tested in rese ....Printed back electrodes enabling low-cost perovskite solar cells. This project aims to address back electrode material, a bottleneck functional material in state-of-the-art perovskite solar cells (PSCs). By engineering printable and conductive materials based on carbon and gold nanowires, the project expects to enable highly-efficient and scalable PSCs while reducing cost of materials and production. These expected outcomes are to be implemented in PSCs and their impact rigorously tested in research cells to large-area PSCs modules produced through industry-relevant, scalable, and low-cost printing and coating methods. This will provide significant benefits to Australian industry, from small to medium enterprises to larger utility power companies, while creating economic opportunities and enabling sustainable societies.Read moreRead less
High efficiency dye-sensitised solar cells containing multiple sensitisers. This project aims to develop a new scalable approach suitable for industrial production of high efficiency dye-sensitised solar cells (DSCs) on both glass and flexible polymer substrates. The success of the project would be a breakthrough in DSC technology, bringing the technology a significant step closer to wide-spread commercial applications.