Discovery Early Career Researcher Award - Grant ID: DE240101170
Funder
Australian Research Council
Funding Amount
$458,237.00
Summary
Design new-generation microscale thermoelectric device. This project aims at realizing ultrahigh thermoelectric power generating performance in the microscale device by developing new theoretical models for thermoelectric power-generation to guide the synergistic thin-film material and device design, and corresponding fabrication. The outcomes are expected to lead to revolutionary development of the thermoelectric technology, significantly extend the application of this emission/vibration/noise/ ....Design new-generation microscale thermoelectric device. This project aims at realizing ultrahigh thermoelectric power generating performance in the microscale device by developing new theoretical models for thermoelectric power-generation to guide the synergistic thin-film material and device design, and corresponding fabrication. The outcomes are expected to lead to revolutionary development of the thermoelectric technology, significantly extend the application of this emission/vibration/noise/service-free technology and expand the corresponding market, which will benefit the wide Australian community academically, educationally, socially, economically and environmentally.Read moreRead less
2D Multiferroics: From Materials Design to Device Conceptualization. This project aims to design new transistors with high efficiency and low energy costing for the storage applications based on two-dimensional multifunctional heterostructures. Extensive computational simulations and joint experiments will be employed to develop fundamental knowledge essential to understanding the phenomena of magnetoelectric coupling, which is used to guide rational device design and implementation. The designe ....2D Multiferroics: From Materials Design to Device Conceptualization. This project aims to design new transistors with high efficiency and low energy costing for the storage applications based on two-dimensional multifunctional heterostructures. Extensive computational simulations and joint experiments will be employed to develop fundamental knowledge essential to understanding the phenomena of magnetoelectric coupling, which is used to guide rational device design and implementation. The designed magnetoelectric heterostructures and the multiferroic devices are expected to provide strong foundations for technological innovations resulting in devices with superior functionality and efficiency. The outcome of the project will significantly benefit high-tech electronics.Read moreRead less
Light Powered Materials for Producing Chemical Fuels. This project aims to develop a hybrid, solar-powered catalytic material for the manufacture of liquid hydrocarbon chemicals, without consuming external heating. The key concept is to transform hydrogen and carbon monoxide into long-chain hydrocarbons over hybrid materials that can convert light energy into heat and simultaneously catalyze the chemical transformation. Investigations on the relations between material synthesis, nanostructures, ....Light Powered Materials for Producing Chemical Fuels. This project aims to develop a hybrid, solar-powered catalytic material for the manufacture of liquid hydrocarbon chemicals, without consuming external heating. The key concept is to transform hydrogen and carbon monoxide into long-chain hydrocarbons over hybrid materials that can convert light energy into heat and simultaneously catalyze the chemical transformation. Investigations on the relations between material synthesis, nanostructures, and performance of the new catalysis processes will be conducted using experiments and theoretical computation. Expected outcomes include low cost and efficient materials for solar-to-fuel conversion, will provide benefits to low-carbon living, new clean energy resource and environmental protections.Read moreRead less
2D oxide supported single-atom catalysts for sustainable fuel generation. This project aims to develop two-dimensional oxide supported single-atom catalysts for sustainable fuel generation from water and CO2 using combined theoretical and experimental investigations. The outcomes of this project will offer atomic and electronic level principles in designing high-performance catalysts and provide novel approaches on green fuel generations for emerging energy technologies. The success of this proj ....2D oxide supported single-atom catalysts for sustainable fuel generation. This project aims to develop two-dimensional oxide supported single-atom catalysts for sustainable fuel generation from water and CO2 using combined theoretical and experimental investigations. The outcomes of this project will offer atomic and electronic level principles in designing high-performance catalysts and provide novel approaches on green fuel generations for emerging energy technologies. The success of this project will meet the knowledge gap between advanced materials and practical sustainable energy technologies, and contribute to the development of sustainable society of Australia and international community by supplying low-cost and green fuels.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100519
Funder
Australian Research Council
Funding Amount
$420,287.00
Summary
Solving key issues in wearable thermoelectrics for practical applications. Wearable thermoelectrics can directly harvest electricity from body heat, offering a new technology to charge wearable electronics sustainably, but their unsatisfied performance and durability limit their applications. This project aims to design efficient and durable wearable thermoelectrics based on novel carbon/polymer/semiconductor (CPS) hybrid films. The key breakthrough is to develop advanced hybrid materials and de ....Solving key issues in wearable thermoelectrics for practical applications. Wearable thermoelectrics can directly harvest electricity from body heat, offering a new technology to charge wearable electronics sustainably, but their unsatisfied performance and durability limit their applications. This project aims to design efficient and durable wearable thermoelectrics based on novel carbon/polymer/semiconductor (CPS) hybrid films. The key breakthrough is to develop advanced hybrid materials and devices with record-high thermoelectric performance, high stability, and high durability to tackle long-lasting practical application issues. The expected outcomes will lead to innovative technology for energy conversion and advanced manufacturing and place Australia at the forefront of energy and manufacturing.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100623
Funder
Australian Research Council
Funding Amount
$412,037.00
Summary
New electrodes for green electrochemical carbon dioxide capture. This project aims to develop new electrochemical carbon capture technology. By designing and fabricating new functional electrodes and high-performance electrochemical devices based on water and driven by renewable electricity, this project will enhance the ability to capture CO2, the primary greenhouse gas that causes global climate change. Expected outcomes include new multi-dimension electrodes with unique chemistry and state-of ....New electrodes for green electrochemical carbon dioxide capture. This project aims to develop new electrochemical carbon capture technology. By designing and fabricating new functional electrodes and high-performance electrochemical devices based on water and driven by renewable electricity, this project will enhance the ability to capture CO2, the primary greenhouse gas that causes global climate change. Expected outcomes include new multi-dimension electrodes with unique chemistry and state-of-the-art CO2 capture devices plus in-depth knowledge of electrochemical CO2 capture mechanisms for optimised device design and control. Benefits include the development of circular carbon economies with capabilities to effectively capture CO2, supporting Australian industries to achieve net zero emissions by 2050.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240101045
Funder
Australian Research Council
Funding Amount
$448,407.00
Summary
Bioinspired 2D nanocatalysts for inorganic nitrogen cycle. This project aims to develop novel catalysts for high-efficient nitrogen fixation by learning from the natural enzymes, which can convert nitrogen or nitrate into reactive ammonia at very mild conditions. It is expected that the enzyme-mimicking catalysts possessing the nitrogen active sites similar with the natural enzymes will allow the effective fixation of nitrogen from both the atmosphere and the nitrogen excessively fertilized envi ....Bioinspired 2D nanocatalysts for inorganic nitrogen cycle. This project aims to develop novel catalysts for high-efficient nitrogen fixation by learning from the natural enzymes, which can convert nitrogen or nitrate into reactive ammonia at very mild conditions. It is expected that the enzyme-mimicking catalysts possessing the nitrogen active sites similar with the natural enzymes will allow the effective fixation of nitrogen from both the atmosphere and the nitrogen excessively fertilized environment into reusable ammonia. The outcomes of this project will provide a sustainable approach to solve the issues in current unbalanced inorganic nitrogen cycle in the world and contribute to a green artificial nitrogen cycle while with minimized environmental impact.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100163
Funder
Australian Research Council
Funding Amount
$426,780.00
Summary
Overcoming the Intrinsic Instability of Perovskites Materials and Devices. This project aims to improve the intrinsic stability of metal halide perovskite energy materials for advanced optoelectronic applications. The key concept is to suppress the phase-segregation for alloyed perovskite by interstitial management as well as develop low-temperature crystallization for non-alloyed perovskite through rational design of the intermediate phase evolution, which has the potential to generate new know ....Overcoming the Intrinsic Instability of Perovskites Materials and Devices. This project aims to improve the intrinsic stability of metal halide perovskite energy materials for advanced optoelectronic applications. The key concept is to suppress the phase-segregation for alloyed perovskite by interstitial management as well as develop low-temperature crystallization for non-alloyed perovskite through rational design of the intermediate phase evolution, which has the potential to generate new knowledge in addressing the key challenge on the operational stability of perovskite devices. The outcomes are expected to deliver valuable intellectual property to accelerate the commercialization of perovskite technology, enabling low-cost utilization of solar energy for a sustainable and low carbon-emission economy.Read moreRead less