Perovskite-silicon tandem solar cells: a pathway to 30 per cent efficiency. This project aims to develop a new type of solar cell that is much more efficient than today’s commercial silicon solar cells. Increasing cell efficiency is one of the most effective ways to reduce the cost of solar electricity, but silicon cells are approaching practical and theoretical limits. This project expects to boost the efficiency of silicon solar cells by adding a low-cost solar cell on top to create a tandem d ....Perovskite-silicon tandem solar cells: a pathway to 30 per cent efficiency. This project aims to develop a new type of solar cell that is much more efficient than today’s commercial silicon solar cells. Increasing cell efficiency is one of the most effective ways to reduce the cost of solar electricity, but silicon cells are approaching practical and theoretical limits. This project expects to boost the efficiency of silicon solar cells by adding a low-cost solar cell on top to create a tandem device. The expected outcome is a solar cell that can convert more than 30 per cent of incident sunlight into electricity, compared to 20-25 per cent for current cells. Developing cheap, high efficiency solar cells should further reduce the cost of solar electricity, and accelerate the uptake of clean energy.Read moreRead less
High Performance Monolithic Perovskite Photocapacitors. Monolithic perovskite photocapacitor (MPPC) consisted of integrated energy harvesting perovskite solar cell and energy storage supercapacitor through an internally shared electrode can deliver stable electricity by harnessing solar energy. The performance of MPPC is dependent of properties of the shared electrode materials. This project aims to synthesis carbon materials with tailored surface, electrical and structure properties that are re ....High Performance Monolithic Perovskite Photocapacitors. Monolithic perovskite photocapacitor (MPPC) consisted of integrated energy harvesting perovskite solar cell and energy storage supercapacitor through an internally shared electrode can deliver stable electricity by harnessing solar energy. The performance of MPPC is dependent of properties of the shared electrode materials. This project aims to synthesis carbon materials with tailored surface, electrical and structure properties that are required to make a highly functioning shared electrode in MPPC. The goal is to fabricate stable, high performance MPPC. Successful achievement of the outcomes will enable cost-effective, reliable, solar electricity, placing Australia at the forefront of exploiting photovoltaics technologies.Read moreRead less
High performance durable perovskite solar cells for space applications . There has been a rapid growth in space exploration and experimentation fuelled by global support. Space hardware needs to be powered by a sustainable source of energy. The use of solar photovoltaics is the preferred choice. As we move into the era of 'commercial space', cost will become paramount necessitating the development of new cost effective photovoltaic technologies. Metal halide perovskite solar cells show the great ....High performance durable perovskite solar cells for space applications . There has been a rapid growth in space exploration and experimentation fuelled by global support. Space hardware needs to be powered by a sustainable source of energy. The use of solar photovoltaics is the preferred choice. As we move into the era of 'commercial space', cost will become paramount necessitating the development of new cost effective photovoltaic technologies. Metal halide perovskite solar cells show the greatest potential. They have a higher power to weight ratio and are significantly cheaper to be manufactured compared to incumbent space cells. This project aims to develop and demonstrate perovskite solar cells to achieve high areal power conversion efficiencies and long operating lifetimes withstanding space environment. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101129
Funder
Australian Research Council
Funding Amount
$425,948.00
Summary
Two-Dimensional Material Tandem Detectors for Polarimetry and Spectroscopy. The aim of this project is to leverage the fundamental advantages that two-dimensional (2D) materials could provide to vertically-stacked (tandem) photodetectors. The strong absorption, tunable bandgap and polarisation dependence that many 2D materials exhibit, provides a means by which to detect properties of light. This topic is significant because it could overcome current cost/performance issues of tandem detectors, .... Two-Dimensional Material Tandem Detectors for Polarimetry and Spectroscopy. The aim of this project is to leverage the fundamental advantages that two-dimensional (2D) materials could provide to vertically-stacked (tandem) photodetectors. The strong absorption, tunable bandgap and polarisation dependence that many 2D materials exhibit, provides a means by which to detect properties of light. This topic is significant because it could overcome current cost/performance issues of tandem detectors, enabling widespread usage. The expected project outcome is the development of a novel tandem 2D detector, which as a single detector/pixel, can extract the intensity, polarisation and wavelength region of incoming light. This would provide benefits for many future applications, including machine vision and aerial surveying.Read moreRead less
Advanced electrocatalysts for ammonia synthesis with validated analysis. Ammonia is one of the most produced chemicals worldwide but current manufacturing industries consume massive amounts of energy and emit harmful greenhouse gases. This project aims to develop a sustainable electrochemical system for ammonia synthesis using electricity and atmospheric nitrogen. A family of porous catalysts with nanoconfined ionic liquids will be developed to drive nitrogen reduction by enhancing the reaction ....Advanced electrocatalysts for ammonia synthesis with validated analysis. Ammonia is one of the most produced chemicals worldwide but current manufacturing industries consume massive amounts of energy and emit harmful greenhouse gases. This project aims to develop a sustainable electrochemical system for ammonia synthesis using electricity and atmospheric nitrogen. A family of porous catalysts with nanoconfined ionic liquids will be developed to drive nitrogen reduction by enhancing the reaction kinetics. Rigorous experimental protocols and novel analytical methods will be developed for quantification of electro-synthesised ammonia. A prototype gas diffusion layer-assisted electrolyser will be demonstrated by coupling with oxygen evolution reactions for selective ammonia synthesis at a reasonable production rate.Read moreRead less
Stable perovskite-unlocking the full potential of low-cost solar cells. Despite impressive conversion efficiency, the perovskites' poor stability impedes their commercialization. This project aims to develop strategies for stable perovskite solar cells. This will be realized by a thorough understanding of the degradation origins with stimuli, and development of degradation mitigation strategies including materials and interfaces engineering, defect control and passivation, synergized by a system ....Stable perovskite-unlocking the full potential of low-cost solar cells. Despite impressive conversion efficiency, the perovskites' poor stability impedes their commercialization. This project aims to develop strategies for stable perovskite solar cells. This will be realized by a thorough understanding of the degradation origins with stimuli, and development of degradation mitigation strategies including materials and interfaces engineering, defect control and passivation, synergized by a systematic degradation evaluation, state-of-art multi-scale material and device characterizations and device modeling providing feedback for optimization. The project will bring new scientific findings, key technological step-change solutions, unlocking the full potential of perovskites for cheaper photovoltaic technologies.
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Solid Oxide Electrolysis Cells with Novel Perovskite-based Cathode. The electrochemical reduction of CO2 and steam to value-added fuels in a high-temperature solid oxide electrolysis cell (SOEC) is practically promising, but technologically challenging. This project aims to develop next generation SOECs using a perovskite-based cathode and scale-up engineering for rapid, bulk production of H2, CO and syngas fuels. Expected outcomes include material engineering, new knowledge on energy conversion ....Solid Oxide Electrolysis Cells with Novel Perovskite-based Cathode. The electrochemical reduction of CO2 and steam to value-added fuels in a high-temperature solid oxide electrolysis cell (SOEC) is practically promising, but technologically challenging. This project aims to develop next generation SOECs using a perovskite-based cathode and scale-up engineering for rapid, bulk production of H2, CO and syngas fuels. Expected outcomes include material engineering, new knowledge on energy conversion technology, and advanced manufacturing technologies. The success of the project will provide a practical solution to reduce fossil CO2 emissions and potential technology for hydrogen production. These will significantly aid Australia in important climate goals and ambitions.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
Anion Exchange Membrane Water Electrolysis for Clean Hydrogen Production. Low-cost and robust water electrolysis technology is a cornerstone towards the success of the hydrogen economy. This project aims to develop next generation anion exchange membrane water electrolyser technologies for low-cost and high-efficiency clean hydrogen production and renewable energy storage. Novel non-precious transition metal-based catalysts with high intrinsic activity, large surface area and super-hydrophilic s ....Anion Exchange Membrane Water Electrolysis for Clean Hydrogen Production. Low-cost and robust water electrolysis technology is a cornerstone towards the success of the hydrogen economy. This project aims to develop next generation anion exchange membrane water electrolyser technologies for low-cost and high-efficiency clean hydrogen production and renewable energy storage. Novel non-precious transition metal-based catalysts with high intrinsic activity, large surface area and super-hydrophilic surfaces will be developed, and their mechanism and stability within membrane electrode assemblies understood by using operando spectroscopy, electrochemistry and 3D X-ray imaging characterisations. An efficient anion exchange membrane water electrolyser prototype made entirely of non-precious materials is to be devised. Read moreRead less