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
Enhanced Waste Heat Recovery from Low-grade Heat Sources Using a Novel Supercritical Power Cycle. Compared with conventional technologies for waste heat recovery, GRANEX cycle offers higher thermal efficiencies, better economics and a greater degree of robustness. If deployed ascross the country to recover even 10% of the nation's waste heat, it would reduce greenhouse emissions by 9 mega tonne which is roughly 1.6% of the annual national emissions. That is equivalent to the yearly CO2 emissions ....Enhanced Waste Heat Recovery from Low-grade Heat Sources Using a Novel Supercritical Power Cycle. Compared with conventional technologies for waste heat recovery, GRANEX cycle offers higher thermal efficiencies, better economics and a greater degree of robustness. If deployed ascross the country to recover even 10% of the nation's waste heat, it would reduce greenhouse emissions by 9 mega tonne which is roughly 1.6% of the annual national emissions. That is equivalent to the yearly CO2 emissions from 648,000 houses or 2 million cars. The proposed research will place Australia within the forefront of the research and development activities in the field of waste heat recovery and will clearly contribute to the Federal Government’s effort in the National Research Priority 1, An Environmentally Sustainable Australia.Read moreRead less
Development of a fuel control system for small two-stroke engines. The two-stroke engine is well known not only for its mechanical simplicity and power-to-weight advantages, but also for its high hydrocarbon emission caused by fuel short-circuiting. Driven by new regulations, developing new technologies for small two-stroke engines to meet pollutant emission standards has become urgent. This project aims to develop a fuel control system for reducing hydrocarbon and other emissions of a two-strok ....Development of a fuel control system for small two-stroke engines. The two-stroke engine is well known not only for its mechanical simplicity and power-to-weight advantages, but also for its high hydrocarbon emission caused by fuel short-circuiting. Driven by new regulations, developing new technologies for small two-stroke engines to meet pollutant emission standards has become urgent. This project aims to develop a fuel control system for reducing hydrocarbon and other emissions of a two-stroke engine designed and produced by Australia's leading lawnmower manufacturer. The knowledge and technology developed will be broadly applicable. By reducing engine pollutant emissions and improving fuel energy efficiency, this research addresses environmental and energy efficiency imperatives.Read moreRead less
Lowering noise emissions from gas turbines. This project aims to advance our understanding of the transmission and radiation of structure-borne noise in ductwork. The project expects to generate new and innovative techniques to lower structure-borne noise from the intake and exhaust systems used by gas turbines in the power generation industry. Expected outcomes include the development of advanced computational models, that are validated against experiment, and suitable for integration into a co ....Lowering noise emissions from gas turbines. This project aims to advance our understanding of the transmission and radiation of structure-borne noise in ductwork. The project expects to generate new and innovative techniques to lower structure-borne noise from the intake and exhaust systems used by gas turbines in the power generation industry. Expected outcomes include the development of advanced computational models, that are validated against experiment, and suitable for integration into a commercial design process. This will provide significant benefits for organisations working in the noise control industry, and lead to new ways of lowering environmental noise caused by ducts and pipes.Read moreRead less
The use of numerical and experimental techniques to develop energy efficient open refrigerated display cabinets. This project will provide knowledge for Australian industry to develop new energy efficient refrigerated display cabinets, putting Australia in the forefront of commercial refrigeration display cabinet technologies. This will have a significant impact on sustainability of our environment and will assist Australia to meet present and future international climate obligations by contrib ....The use of numerical and experimental techniques to develop energy efficient open refrigerated display cabinets. This project will provide knowledge for Australian industry to develop new energy efficient refrigerated display cabinets, putting Australia in the forefront of commercial refrigeration display cabinet technologies. This will have a significant impact on sustainability of our environment and will assist Australia to meet present and future international climate obligations by contributing to the reduction of greenhouse emissions. The Government has already introduced new MEPS levels, and are planning to increase these to more stringent levels in 2007. The development of the techniques proposed in this application will be essential for manufacturers if they are to economically meet these MEPS level requirements. Read moreRead less
Heat Transfer Enhancement Techniques for Air Conditioning and Refrigeration Equipment. The proposed Project will make significant contribution towards the both fundamental understanding of heat transfer enhancement using dimpled surfaces and the design of heat exchangers and, in particular to the application of dimpled surfaces in air conditioning and refrigeration industries. Unlike the previous CFD studies which have been made on the assumptions that the flow is steady and decoupled from the ....Heat Transfer Enhancement Techniques for Air Conditioning and Refrigeration Equipment. The proposed Project will make significant contribution towards the both fundamental understanding of heat transfer enhancement using dimpled surfaces and the design of heat exchangers and, in particular to the application of dimpled surfaces in air conditioning and refrigeration industries. Unlike the previous CFD studies which have been made on the assumptions that the flow is steady and decoupled from the heat transfer calculations in this Project the fully coupled problem will be solved, in which unsteady flows are allowed to occur over a dimpled surfaces. As a result we will be able to more accurately determine the resultant effects on the pressure drop and heat transfer. Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH180100020
Funder
Australian Research Council
Funding Amount
$3,058,152.00
Summary
ARC Research Hub for Integrated Energy Storage Solutions. The ARC Research Hub for Integrated Energy Storage Solutions aims to develop advanced energy storage technologies, including printed batteries, structural supercapacitors, innovative fuel cells and power-to-gas systems. It plans to integrate these storage solutions with existing energy networks and applications using novel storage monitoring, control and optimisation technologies. The Hub is expected to generate new knowledge in storage t ....ARC Research Hub for Integrated Energy Storage Solutions. The ARC Research Hub for Integrated Energy Storage Solutions aims to develop advanced energy storage technologies, including printed batteries, structural supercapacitors, innovative fuel cells and power-to-gas systems. It plans to integrate these storage solutions with existing energy networks and applications using novel storage monitoring, control and optimisation technologies. The Hub is expected to generate new knowledge in storage technology manufacturing, control and management. Expected outcomes include cheaper and more effective storage devices and better storage integration solutions, supporting renewables, reducing carbon emissions, and improving efficiency in the energy sector. Resulting benefits include a more sustainable, secure, reliable and economically efficient energy supply. This Hub will contribute to improving the economic efficiency of Australia’s energy sector.Read moreRead less
Building Australia's Electric Vehicle Fast Charging Infrastructure. This project aims to enhance the resilience, safety, and efficiency of electricity grids operated with fast-charging Electric Vehicles (EVs) by developing new control and optimisation frameworks. This project expects to develop new robust controllers for EV fast-charging infrastructure operated in coordination with wind and solar generated electricity. Expected project outcomes include enabling fast-charge EV infrastructure to b ....Building Australia's Electric Vehicle Fast Charging Infrastructure. This project aims to enhance the resilience, safety, and efficiency of electricity grids operated with fast-charging Electric Vehicles (EVs) by developing new control and optimisation frameworks. This project expects to develop new robust controllers for EV fast-charging infrastructure operated in coordination with wind and solar generated electricity. Expected project outcomes include enabling fast-charge EV infrastructure to be developed and deployed in Australia by the industry partner SwitchDin. Expected benefits including enabling significant reduction in carbon emissions from the transportation sector, accelerating the energy transition to renewables, and placing Australian industry at the forefront of EV grid integration technology.Read moreRead less
High-voltage electrode materials for lithium-ion batteries. This project aims to establish a complete battery research system and develop high-voltage electrode materials for lithium-ion batteries through mechanistic understanding obtained in operando studies. Lithium-ion batteries are the most promising choice for portable electronic devices, including electric vehicles, due to their high power and energy performance compared with other battery technologies. The success of this project is expec ....High-voltage electrode materials for lithium-ion batteries. This project aims to establish a complete battery research system and develop high-voltage electrode materials for lithium-ion batteries through mechanistic understanding obtained in operando studies. Lithium-ion batteries are the most promising choice for portable electronic devices, including electric vehicles, due to their high power and energy performance compared with other battery technologies. The success of this project is expected to advance fundamental understanding of lithium-ion batteries, and provide techniques to develop a promising high-energy and high-power battery system.Read moreRead less
An innovative wind power system primarily for urban environments. The project aims to develop a novel rotor vane array wind power system that can be used as a roof fence or balcony on existing or new buildings. Traditional wind turbines cannot fully realise the potential of excellent wind speed in tall buildings because of space efficiency, visual impact, and danger or noise issues. The system to be developed in the project incorporates advanced active flow control that addresses these issues. T ....An innovative wind power system primarily for urban environments. The project aims to develop a novel rotor vane array wind power system that can be used as a roof fence or balcony on existing or new buildings. Traditional wind turbines cannot fully realise the potential of excellent wind speed in tall buildings because of space efficiency, visual impact, and danger or noise issues. The system to be developed in the project incorporates advanced active flow control that addresses these issues. The project plans to conduct a structured program of numerical and experimental studies, the intended outcomes of which will contribute to energy security, progress towards zero emissions and sustainable living, and lead to innovative architecture of the future.Read moreRead less