Solar-driven thermochemical dissociation of carbon dioxide and water to produce carbon-neutral fuels. The biggest challenge to humanity of the century is to develop enabling clean energy resources to encounter rapidly diminished fossil fuel and accelerated global warming conditions. This project will offer a solution by developing a unique solar-driven thermochemical system capable of cleaving carbon dioxide and water to produce artificial syngas.
Laser Diagnostics of Soot Formation in Precessing Jet Flames. In many practical combustion systems (e.g., boiler furnaces and rotary kilns), flame radiation is the major contributor to the required heat transfer. Soot formation is a means of enhancing flame radiation provided the soot is completely oxidised within the flame so that there are no soot emissions. The enhanced flame radiation can have a significant economic and environmental impact on plant operation (changes to the parameters tha ....Laser Diagnostics of Soot Formation in Precessing Jet Flames. In many practical combustion systems (e.g., boiler furnaces and rotary kilns), flame radiation is the major contributor to the required heat transfer. Soot formation is a means of enhancing flame radiation provided the soot is completely oxidised within the flame so that there are no soot emissions. The enhanced flame radiation can have a significant economic and environmental impact on plant operation (changes to the parameters that influence soot formation can also influence NOx and greenhouse gas emissions). The objectives of this project are to identify and quantify the operating parameters that influence soot formation and destruction in such flames.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220101484
Funder
Australian Research Council
Funding Amount
$449,000.00
Summary
Towards Electrochemical Fertiliser Production Powered by Renewable Energy. The electrochemical manufacturing system is a sustainable alternative to traditional fertiliser manufacturing plants. The system can be assembled inexpensively and readily integrated into the renewable electricity grid, solving the greenhouse gas emission issues of the fertiliser plants. This project will identify ground-breaking electrochemical pathways for urea fertiliser and other value-added C-N containing chemicals s ....Towards Electrochemical Fertiliser Production Powered by Renewable Energy. The electrochemical manufacturing system is a sustainable alternative to traditional fertiliser manufacturing plants. The system can be assembled inexpensively and readily integrated into the renewable electricity grid, solving the greenhouse gas emission issues of the fertiliser plants. This project will identify ground-breaking electrochemical pathways for urea fertiliser and other value-added C-N containing chemicals synthesis. Gaseous CO2 and N2 will be electrochemically reacted to produce the C-N bonds. Therefore, a suite of new materials and electrochemical systems for sustainable fertiliser manufacturing will be developed. It is anticipated that the technology will revolutionise Australian fertiliser manufacturing and agriculture.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989747
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
Ultrafast Dynamics Measurement Facility for the Physical, Biochemical, and Materials Sciences. The term "ultrafast revolution" describes the transformations in science due to ultrafast laser technology. Today, ultrafast lasers are used in surgery, nanomaterial fabrication, biomedical imaging, spectroscopic investigations, and new applications are still emerging. This facility will draw together leading chemists, physicists, and engineers to investigate key ultrafast processes and phenomena in th ....Ultrafast Dynamics Measurement Facility for the Physical, Biochemical, and Materials Sciences. The term "ultrafast revolution" describes the transformations in science due to ultrafast laser technology. Today, ultrafast lasers are used in surgery, nanomaterial fabrication, biomedical imaging, spectroscopic investigations, and new applications are still emerging. This facility will draw together leading chemists, physicists, and engineers to investigate key ultrafast processes and phenomena in the physical, biochemical and material sciences. This is of strategic importance to keep Australia at the global forefront for scientific endeavours, supporting new research and commercial opportunities. This facility will also produce highly trained graduates, who will find employment in industry throughout Australia and globally.Read moreRead less
Development of Nanocrystalline Transition Metal Oxide and Polymer-Transition Metal Oxide Composite Materials for Rechargeable Lithium Battery Applications. Recent work by the applicants has shown that nanocrystalline titanates and aluminates hold considerable promise as lithium battery electrodes. Nanocrystalline anatase materials showed considerably greater lithium intercalation ratios compared with their microcrystalline counterparts, and doping with vanadium showed further improvements in ....Development of Nanocrystalline Transition Metal Oxide and Polymer-Transition Metal Oxide Composite Materials for Rechargeable Lithium Battery Applications. Recent work by the applicants has shown that nanocrystalline titanates and aluminates hold considerable promise as lithium battery electrodes. Nanocrystalline anatase materials showed considerably greater lithium intercalation ratios compared with their microcrystalline counterparts, and doping with vanadium showed further improvements in capacity. Sol-gel synthesised V-doped anatase materials produced an initial discharge capacity of 428 Ah/kg compared with only 280 mAh/kg for the undoped anatase electrode in the same Li test cell.In this project different dopants and preparation conditions will be investigated to produce nanocrystalline rutile and aluminate materials as potential candidates for high capacity lithium battery applications.Read moreRead less
Photodissociation Dynamics of Radicals and Molecules. Photodissociation dynamics involves studying fundamental chemical processes that underpin all chemical reactivity. We address three of the important unanswered questions in this field: i) how do the lessons learned from small molecules transfer to larger molecules? ii) can one control chemical reactivity by selecting specific states of the reactant?; and iii) are the dynamics of radicals fundamentally different to stable molecules? We wi ....Photodissociation Dynamics of Radicals and Molecules. Photodissociation dynamics involves studying fundamental chemical processes that underpin all chemical reactivity. We address three of the important unanswered questions in this field: i) how do the lessons learned from small molecules transfer to larger molecules? ii) can one control chemical reactivity by selecting specific states of the reactant?; and iii) are the dynamics of radicals fundamentally different to stable molecules? We will combine expertise in large molecule spectroscopy and photodissociation dynamics with technology in radical production to provide insight into these fundamental questions. Photodissociation dynamics is firmly embedded in photon science and technology.Read moreRead less
Fundamentals and applications of dynamic interfacial forces in soft matter. The proposed program will make an internationally significant contribution to the fundamental understanding of soft matter on the nanoscale. This has a direct impact upon processes that are key to a wide range of Australian industries ranging from the manufacture of functional foods to minerals recovery to pharmaceutical formulation, where innovative solutions can substantially improve productivity, increase export pote ....Fundamentals and applications of dynamic interfacial forces in soft matter. The proposed program will make an internationally significant contribution to the fundamental understanding of soft matter on the nanoscale. This has a direct impact upon processes that are key to a wide range of Australian industries ranging from the manufacture of functional foods to minerals recovery to pharmaceutical formulation, where innovative solutions can substantially improve productivity, increase export potential and reduce environmental impact. The outcomes of this work, in the form of high impact papers and conference presentations, will build and enhance Australia's reputation as a world leader in nanotechnology and colloid science. Read moreRead less
Model Studies of the Wettability of Reservoir and Seal Rocks as Recovered and After Treatments to Alter Surface Properties. Key contributions will be made to the science that underpins petroleum recovery. The combination of diverse expertise in interfacial physics and chemistry, petroleum geology and petrophysics provides a large innovative potential for the industry. Two graduate students will be educated in a rich multi-disciplinary research environment with a strong emphasis on both academic ....Model Studies of the Wettability of Reservoir and Seal Rocks as Recovered and After Treatments to Alter Surface Properties. Key contributions will be made to the science that underpins petroleum recovery. The combination of diverse expertise in interfacial physics and chemistry, petroleum geology and petrophysics provides a large innovative potential for the industry. Two graduate students will be educated in a rich multi-disciplinary research environment with a strong emphasis on both academic and industrial aspects of the problems. The research conducted will enable the industrial partners to improve existing technologies for predicting where oil and gas is trapped and for petroleum recovery.
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
Electrocatalytic Generation of Ammonia from Air and Water. The aim is to directly convert nitrogen under mild conditions, using renewable power, to form ammonia for fertilisers and fuels, enabled by new, nanostructured, electrocatalysts based on single-sheet and composite materials. Unlike nitrogen fixation using a three-electrode system, the project will use a novel mixed gas- and liquid-phase electrocatalytic nitrogen reduction two-electrode reactor. Based on fuel cells, it is designed to acce ....Electrocatalytic Generation of Ammonia from Air and Water. The aim is to directly convert nitrogen under mild conditions, using renewable power, to form ammonia for fertilisers and fuels, enabled by new, nanostructured, electrocatalysts based on single-sheet and composite materials. Unlike nitrogen fixation using a three-electrode system, the project will use a novel mixed gas- and liquid-phase electrocatalytic nitrogen reduction two-electrode reactor. Based on fuel cells, it is designed to accelerate the naturally sluggish nitrogen reduction reaction, NRR, significantly improving the reaction rate and selectivity. The project will also gain atomic-level understanding of the mechanism of NRR, based on in-situ spectroscopies used under operando conditions, e.g., Raman or X-ray absorption.Read moreRead less