Artificial photosynthesis for solar fuel production. We aim to realise an artificial system that converts solar energy to hydrogen (artificial photosynthesis). The resulting device will be able to 'split' water into oxygen and hydrogen, whereas hydrogen can be further converted into electricity or heat (combustion).
Benchmarking of advanced scattering probes for materials characterisation. The project seeks to establish the accuracy and validity of different methods of nanoscale structure determination. Nanoscale structure is crucial to the properties of many modern materials with diverse applications: e.g. sensors and actuators in cell phones; smart shock absorbers and fuel injectors in cars; memory devices; drug delivery devices.
Interactions between linear and interfacial crystalline defects and their impact on mechanical properties in nanostructured metals and alloys. The project aims to apply in-situ deformation transmission electron microscopy to investigate the interactions among crystalline defects in nanostructured metallic materials and to explore the effect of the interactions on mechanical properties. The results will guide the structural design of nanomaterials with superior mechanical properties.
Sodium ion interactions with biomass-derived hard carbon electrodes. This project aims to investigate sodium ion behavior when electrochemically interacting with hard carbon electrode materials by using both in-situ and ex-situ techniques in combination with advanced computational methods. This project expects to generate new knowledge and establish structure-property-performance correlations, thus providing guidelines and strategies for synthesising cost-effective electrode materials from bioma ....Sodium ion interactions with biomass-derived hard carbon electrodes. This project aims to investigate sodium ion behavior when electrochemically interacting with hard carbon electrode materials by using both in-situ and ex-situ techniques in combination with advanced computational methods. This project expects to generate new knowledge and establish structure-property-performance correlations, thus providing guidelines and strategies for synthesising cost-effective electrode materials from biomass for developing sustainable sodium-ion batteries. The intended outcome of this project includes knowledge advancement, enhanced capability to build international collaborations, training of early career researchers and students, and positioning Australia on the world map as a world-leading nation in energy storage.Read moreRead less
Multimodal nanostructured metals and alloys with high tensile ductility and strength. This project will develop a new class of advanced multimodal nanostructured materials that have high tensile ductility, strength, and excellent fracture toughness. This work is important for the transportation industry as the new materials provide potential in creating lightweight structures, leading to the reduction of carbon dioxide emission.
Discovery Early Career Researcher Award - Grant ID: DE220101577
Funder
Australian Research Council
Funding Amount
$446,639.00
Summary
Two-Dimensional Covalent Organic Framework for Next-Generation Batteries. This project aims to develop advanced two-dimensional (2D) covalent organic framework (COF) materials for sodium and potassium-ion batteries. It expects to generate a new family of few-layered 2D COF materials and their 2D-2D heterostructured composites with improved electrochemical properties, and develop processing technologies and fundamental understanding of COF-based electrodes for flexible sodium and potassium-ion ba ....Two-Dimensional Covalent Organic Framework for Next-Generation Batteries. This project aims to develop advanced two-dimensional (2D) covalent organic framework (COF) materials for sodium and potassium-ion batteries. It expects to generate a new family of few-layered 2D COF materials and their 2D-2D heterostructured composites with improved electrochemical properties, and develop processing technologies and fundamental understanding of COF-based electrodes for flexible sodium and potassium-ion batteries. Expected outcomes include novel materials, technologies, and energy-storage options for Australia. Significant economic and environmental benefits are expected from developing advanced sodium and potassium-ion batteries with low cost, high energy density, and improved safety for renewable energy storage.Read moreRead less
Hydrogen fuel cells with non-precious metal cathode catalysts. Low-cost and robust fuel cell technology is a cornerstone towards the success of the hydrogen economy. The project aims to address the cost and durability of hydrogen fuel cells by advancing low-cost electrocatalysts for oxygen reduction reactions. Novel non-precious catalysts will be developed, and their stability understood in fuel cells using a new approach with in situ current mapping and X-ray computed tomography. The expected ....Hydrogen fuel cells with non-precious metal cathode catalysts. Low-cost and robust fuel cell technology is a cornerstone towards the success of the hydrogen economy. The project aims to address the cost and durability of hydrogen fuel cells by advancing low-cost electrocatalysts for oxygen reduction reactions. Novel non-precious catalysts will be developed, and their stability understood in fuel cells using a new approach with in situ current mapping and X-ray computed tomography. The expected outcomes of this project include material development, improved characterisation techniques and new knowledge on electrocatalysis. The project will benefit Kohodo Hydrogen Energy by positioning them as an Australian leader in low-cost catalysts, and to Australian industries in developing the hydrogen economy. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220101040
Funder
Australian Research Council
Funding Amount
$424,000.00
Summary
Ultrastable perovskite nanocrystals for high quality optoelectronic devices. This project aims to investigate novel highly efficient luminescent nanomaterials; by utilising perovskite nanocrystals with enhanced stability by coating or mesoporous materials. This project expects to generate new knowledge in the area of energy conversion using interdisciplinary approaches of chemistry, physics, engineering and machine learning. Expected outcomes of this project include higher efficiency display and ....Ultrastable perovskite nanocrystals for high quality optoelectronic devices. This project aims to investigate novel highly efficient luminescent nanomaterials; by utilising perovskite nanocrystals with enhanced stability by coating or mesoporous materials. This project expects to generate new knowledge in the area of energy conversion using interdisciplinary approaches of chemistry, physics, engineering and machine learning. Expected outcomes of this project include higher efficiency display and lighting, better performance of energy harvesting. The cross disciplinary collaborations pave the way to achieve the objectives of this project. This should provide significant benefits, such as better ways to convert energy from renewable sources and more efficient ways to use electrical power for lighting and display.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100187
Funder
Australian Research Council
Funding Amount
$290,000.00
Summary
SA Facility for High Resolution Imaging and Material Characterization. Facility for high resolution imaging and material characterisation: The aim of this project is to establish a facility that will allow researchers to visualise and analyse structure at nanoscale resolutions. The development of the next generation of opto-electronics, electrochemical and biomedical devices requires tools that can quickly visualise and characterise complex materials at multiscale. The new collaborative nano in ....SA Facility for High Resolution Imaging and Material Characterization. Facility for high resolution imaging and material characterisation: The aim of this project is to establish a facility that will allow researchers to visualise and analyse structure at nanoscale resolutions. The development of the next generation of opto-electronics, electrochemical and biomedical devices requires tools that can quickly visualise and characterise complex materials at multiscale. The new collaborative nano infrared thermal analysis facility is essential to meet the demands of a large number of innovative projects conducted by multidisciplinary consortia of researchers. Located in state-of-the art laboratories and managed as open access resources, the facility will enable and advance research in the areas of energy harvesting, environmental monitoring, biomedical devices, food and pharmaceuticals.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL170100101
Funder
Australian Research Council
Funding Amount
$2,843,970.00
Summary
Towards sustainable electrochemical energy storage technology. This project aims to address fundamental issues on electrochemical energy storage technology using sodium-ion capacitors, by designing novel electrode materials and utilising advanced, in-situ and ex-situ instrumental techniques in combination with modern computational simulation methods. The project will lead to a complete understanding of the charge storage mechanism and transport kinetics in sodium-ion capacitors, providing guide ....Towards sustainable electrochemical energy storage technology. This project aims to address fundamental issues on electrochemical energy storage technology using sodium-ion capacitors, by designing novel electrode materials and utilising advanced, in-situ and ex-situ instrumental techniques in combination with modern computational simulation methods. The project will lead to a complete understanding of the charge storage mechanism and transport kinetics in sodium-ion capacitors, providing guidelines for developing sustainable electrochemical energy storage technology. The project expects to generate new knowledge in energy storage including capacity building, training of young scientists, and intellectual property with potential commercialised products.Read moreRead less