Bioinspired tuneable catalysts for renewable ammonia production. The project will design a new solar-powered system for electrosynthesis of ammonia to replace the current energy intensive, non-sustainable process that generates 1.5% of global CO2 emissions. An innovative new system will be developed by combining cutting edge electrochemical, spectroscopic and theoretical methods. Expected key outcomes include novel concepts in the design of advanced materials, and an efficient process for the gr ....Bioinspired tuneable catalysts for renewable ammonia production. The project will design a new solar-powered system for electrosynthesis of ammonia to replace the current energy intensive, non-sustainable process that generates 1.5% of global CO2 emissions. An innovative new system will be developed by combining cutting edge electrochemical, spectroscopic and theoretical methods. Expected key outcomes include novel concepts in the design of advanced materials, and an efficient process for the green ammonia synthesis. Given the strategic importance of ammonia as a future energy carrier for the export of Australian renewables and as a major source of fertilisers, this project should provide significant national economic and ecological benefits and is expected to have a broad reaching global impact.Read moreRead less
Sustainable nitrogen chemistry. The goal of this project is to develop sustainable methods to produce nitrates from air and water, using renewable electricity. This new electrochemical technology will be based on the design of new electrolytes and catalysts supported by advanced theoretical concepts to provide high rate of production and selectivity. This is expected to generate new fundamental knowledge in materials and catalysis science. As traditional production of nitrates for industry and a ....Sustainable nitrogen chemistry. The goal of this project is to develop sustainable methods to produce nitrates from air and water, using renewable electricity. This new electrochemical technology will be based on the design of new electrolytes and catalysts supported by advanced theoretical concepts to provide high rate of production and selectivity. This is expected to generate new fundamental knowledge in materials and catalysis science. As traditional production of nitrates for industry and agriculture generates significant greenhouse gas emissions, the core anticipated outcome of this project is a new, sustainable era of nitrogen chemistry. This is also expected to benefit farmers by providing a process for the generation of sustainable fertilisers on a local basis.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101076
Funder
Australian Research Council
Funding Amount
$426,985.00
Summary
Resolving nanoscale structure-activity for rational electrocatalyst design. This project aims to investigate the structural and functional properties of electrocatalysts at the nanoscale. The project expects to develop state-of-the-art electrochemical imaging technology that can examine the active sites of electrodes during operation. Understanding electrode performance on this scale is expected to enhance our capability to rationally design cheaper and more-efficient electrocatalysts, notably ....Resolving nanoscale structure-activity for rational electrocatalyst design. This project aims to investigate the structural and functional properties of electrocatalysts at the nanoscale. The project expects to develop state-of-the-art electrochemical imaging technology that can examine the active sites of electrodes during operation. Understanding electrode performance on this scale is expected to enhance our capability to rationally design cheaper and more-efficient electrocatalysts, notably for electrochemical carbon dioxide reduction. This should provide significant socio-economic and environmental benefits, through the development of next-generation energy storage and conversion materials that can be utilized by households and businesses to store renewable energy in the form of carbon-neutral fuels.Read moreRead less
New dimensions of electrocatalyst design for sustainable energy future. This project aims to produce valuable chemicals from air, water and Australia’s abundant renewable energy, by developing efficient, robust catalysts for water oxidation, nitrogen reduction and ammonia oxidation — key processes for sustainable production of green fuels and fertilisers. The interdisciplinary project strategy will use a suite of advanced instrumental and theoretical tools to understand and control how catalysts ....New dimensions of electrocatalyst design for sustainable energy future. This project aims to produce valuable chemicals from air, water and Australia’s abundant renewable energy, by developing efficient, robust catalysts for water oxidation, nitrogen reduction and ammonia oxidation — key processes for sustainable production of green fuels and fertilisers. The interdisciplinary project strategy will use a suite of advanced instrumental and theoretical tools to understand and control how catalysts operate. Expected outcomes include new techniques to study catalysts, new catalyst design concepts, and novel high-performance catalytic materials and devices for sustainable electrosynthesis. These new technologies should reduce emissions and help Australia be a world leader in renewable-energy and fertiliser export.Read moreRead less
Medium temperature electrolysis for low-cost carbon dioxide utilization. Carbon dioxide is a notorious greenhouse gas. Its capture, and subsequent storage or utilization, is a major focus not only for researchers, but also for governments trying to meet their obligations of the Paris Agreement on climate change and for industries managing their legal and social responsibilities. This project aims to develop commercially viable medium temperature electrolysers to convert carbon dioxide into value ....Medium temperature electrolysis for low-cost carbon dioxide utilization. Carbon dioxide is a notorious greenhouse gas. Its capture, and subsequent storage or utilization, is a major focus not only for researchers, but also for governments trying to meet their obligations of the Paris Agreement on climate change and for industries managing their legal and social responsibilities. This project aims to develop commercially viable medium temperature electrolysers to convert carbon dioxide into value added chemicals using electricity from renewable sources. New design principles will be developed to generate highly active and selective catalysts with long-term stability. These electrolyzers will be integrated with carbon capture technologies to directly utilize captured carbon dioxide with high energy efficiency.Read moreRead less
Ambient Electrochemical C-N Coupling via Co-electrolysis of N2 and CO2. To overcome the hurdles in N2 fixation (massive energy consumption and CO2 emission), investigators creatively hypothesize that the simultaneous electrocatalytic coupling of N2 and CO2 would enable the selective formation of N-products and thus realize their conversion into N--fertilizers and acetamides. Based on the CI's recent discoveries, this project will develop an innovative / sustainable system, which could promote th ....Ambient Electrochemical C-N Coupling via Co-electrolysis of N2 and CO2. To overcome the hurdles in N2 fixation (massive energy consumption and CO2 emission), investigators creatively hypothesize that the simultaneous electrocatalytic coupling of N2 and CO2 would enable the selective formation of N-products and thus realize their conversion into N--fertilizers and acetamides. Based on the CI's recent discoveries, this project will develop an innovative / sustainable system, which could promote the N2 fixation along with CO2 conversion process, a significant alternative approach to simplify the pathways of C-N bond formation. It will thereby contribute to mitigation of greenhouse emissions and create an ecofriendly protocol/technology for distributed production of C-N products under ambient conditions. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100477
Funder
Australian Research Council
Funding Amount
$420,770.00
Summary
Developing sustainable liquid fuels from carbon dioxide conversion. This project aims to develop new electrochemical materials and systems capable of converting carbon dioxide to liquid fuels. It expects to generate new knowledge in the area of advanced materials and systems for sustainable fuel production by interdisciplinary integration of catalyst design, real-time characterisation and system engineering. Expected outcomes include electrochemical carbon dioxide-to-alcohol systems with commerc ....Developing sustainable liquid fuels from carbon dioxide conversion. This project aims to develop new electrochemical materials and systems capable of converting carbon dioxide to liquid fuels. It expects to generate new knowledge in the area of advanced materials and systems for sustainable fuel production by interdisciplinary integration of catalyst design, real-time characterisation and system engineering. Expected outcomes include electrochemical carbon dioxide-to-alcohol systems with commercially relevant performances and in-depth understanding of reaction mechanisms at nano and molecular levels. Significant economic, energy and environmental benefits are expected from the concerted greenhouse gas emissions reduction and the development of sustainable, clean, non-fossil fuels, enabled by this project.Read moreRead less