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
Nitride materials: In the “bond ionicity Goldilocks zone” for solar energy. Progress towards commercial devices for solar-driven hydrogen generation as well as in-situ electricity generation for vehicles is currently hampered by a lack of earth-abundant, stable, non-toxic semiconductor materials that can be fabricated by scalable methods. This project aims to develop the first scalable solution synthesis methods for a new class of earth-abundant Zn-based nitride semiconductor nanocrystals that h ....Nitride materials: In the “bond ionicity Goldilocks zone” for solar energy. Progress towards commercial devices for solar-driven hydrogen generation as well as in-situ electricity generation for vehicles is currently hampered by a lack of earth-abundant, stable, non-toxic semiconductor materials that can be fabricated by scalable methods. This project aims to develop the first scalable solution synthesis methods for a new class of earth-abundant Zn-based nitride semiconductor nanocrystals that have favourable bond ionicity and establish their optoelectronic properties for renewable energy devices for the first time. Flexible solution processing methods will be exploited to tune surface composition, remove defects and create devices to achieve optimised performance in these challenging new nitride material systems.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
Discovery Early Career Researcher Award - Grant ID: DE210101565
Funder
Australian Research Council
Funding Amount
$423,193.00
Summary
An Emerging Ionic Chalcogenide Perovskites for Solar Energy Conversion. This project aims to develop a library of earth-abundant chalcogenide perovskite nanocrystals (CPNCs) for efficient solar energy conversion applications. The key concept is to design non-toxic and stable CPNCs using a facile solution process for solar-to-electricity and fuel generation. The intended outcomes include a fundamental understanding of the relationships between the synthesis, structure, photophysics, and electroch ....An Emerging Ionic Chalcogenide Perovskites for Solar Energy Conversion. This project aims to develop a library of earth-abundant chalcogenide perovskite nanocrystals (CPNCs) for efficient solar energy conversion applications. The key concept is to design non-toxic and stable CPNCs using a facile solution process for solar-to-electricity and fuel generation. The intended outcomes include a fundamental understanding of the relationships between the synthesis, structure, photophysics, and electrochemistry by advanced modeling and multiscale characterizations and ultimately the solar-to-electricity and fuel generation performances of new material systems. This project will build a national research capacity in an emerging field and put Australia at the forefront of practical solar energy conversion technologies.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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100084
Funder
Australian Research Council
Funding Amount
$269,020.00
Summary
Flexible Flame Aerosol Synthesis Technology. Funding is requested to establish a world-leading fabrication facility for nanostructured materials via flame synthesis. This is a scalable fabrication route used for industrial production of most nanoparticle commodities. The aim is to advance current capabilities by providing control over the reaction environment and flame reaction sources. This will extend the range of feasible materials from the current metal oxides to a broad family of nitrides, ....Flexible Flame Aerosol Synthesis Technology. Funding is requested to establish a world-leading fabrication facility for nanostructured materials via flame synthesis. This is a scalable fabrication route used for industrial production of most nanoparticle commodities. The aim is to advance current capabilities by providing control over the reaction environment and flame reaction sources. This will extend the range of feasible materials from the current metal oxides to a broad family of nitrides, sulphides, and metal-organic frameworks, enabling the engineering of electrocatalysts, optoelectronic- and bio-materials. Benefits are expected in terms of fundamental and applied knowledge generation, with impact to the Australian industry sectors of Advanced Manufacturing, Energy and Health.Read moreRead less
Development of high efficiency nanocatalysts using novel electron beam fabrication and imaging techniques. This project will develop a new approach for fabricating and studying nanocatalysts based on our expertise in electron beam induced deposition (EBID) of nanostructured materials and environmental scanning electron microscopy (ESEM). ESEM will be used to conduct unique, time-resolved studies of nano-scale, catalysed chemical reactions at elevated temperatures and pressures. The project will ....Development of high efficiency nanocatalysts using novel electron beam fabrication and imaging techniques. This project will develop a new approach for fabricating and studying nanocatalysts based on our expertise in electron beam induced deposition (EBID) of nanostructured materials and environmental scanning electron microscopy (ESEM). ESEM will be used to conduct unique, time-resolved studies of nano-scale, catalysed chemical reactions at elevated temperatures and pressures. The project will advance fundamental understanding and applicability of EBID, ESEM and nanocatalysis. It will yield novel, highly efficient, industrially relevant nanocatalysts for the production of renewable (green) and low emission (clean) energy, with particular applications in hydrogen fuel cells and the catalytic oxidation of carbon monoxide.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101669
Funder
Australian Research Council
Funding Amount
$410,316.00
Summary
Hydrogel Electrolytes for Flexible Rechargeable Zinc-Air Batteries. This project aims to advance the development of flexible rechargeable zinc-air batteries (ZABs) by innovating functional hydrogels as solid-state electrolytes. Flexible rechargeable ZABs are the most promising power source for emerging flexible electronics, but lacking of high-performance flexible electrolytes is a critical bottleneck for their applications. Based on hydrogel innovation, this project will address the most critic ....Hydrogel Electrolytes for Flexible Rechargeable Zinc-Air Batteries. This project aims to advance the development of flexible rechargeable zinc-air batteries (ZABs) by innovating functional hydrogels as solid-state electrolytes. Flexible rechargeable ZABs are the most promising power source for emerging flexible electronics, but lacking of high-performance flexible electrolytes is a critical bottleneck for their applications. Based on hydrogel innovation, this project will address the most critical challenges of flexible electrolytes in flexible rechargeable ZABs. Findings from this project will create new knowledge generated from multidisciplinary research and pave the way to realise a new generation of flexible rechargeable ZABs as a highly efficient and durable flexible energy storage technology.Read moreRead less
Highly Efficient Solar Window Technology Enabled by Quantum Dots. The transition to zero-greenhouse gas emitting buildings is hindered by the lack of efficient energy generating building components with good aesthetics. This project will develop integrated solar windows that can effectively convert the facades of urban buildings into energy generation sites, enabled by our nanomaterials having outstanding light emission efficiencies of over 90%, accompanied by our advanced light guiding strategi ....Highly Efficient Solar Window Technology Enabled by Quantum Dots. The transition to zero-greenhouse gas emitting buildings is hindered by the lack of efficient energy generating building components with good aesthetics. This project will develop integrated solar windows that can effectively convert the facades of urban buildings into energy generation sites, enabled by our nanomaterials having outstanding light emission efficiencies of over 90%, accompanied by our advanced light guiding strategies and innovative PV cell integration. This next generation technology can reduce the electricity cost and increase renewable energy adoption, placing Australia in a competitive position in the billion-dollar building integrated photovoltaic market whilst also contributing to decarbonising electricity generation.Read moreRead less
Non-precious fuel cell cathode catalysts from carbon-based nanohybrids: a computational to experimental quest. This joint computational-experimental project will address significant problems including high cost, limited availability and poor performance in traditional platinum-based fuel cell technology. The outcomes are expected to help address global energy problems through the development of inexpensive fuel cell catalysts based on carbon nanohybrids.