Special Research Initiatives - Grant ID: SR180100023
Funder
Australian Research Council
Funding Amount
$940,000.00
Summary
Thermal decomposition of PFAS. This project aims to investigate the thermal decomposition of per- and poly-fluroalkyl substances (PFAS). The project will focus on the catalytic destruction of PFAS reactions at elevated temperatures, which is expected to transform PFAS in a controlled and predictable way into benign products. By understanding the fate of these compounds during thermal decomposition, the project will allow the development of a new technology aimed at treating materials which have ....Thermal decomposition of PFAS. This project aims to investigate the thermal decomposition of per- and poly-fluroalkyl substances (PFAS). The project will focus on the catalytic destruction of PFAS reactions at elevated temperatures, which is expected to transform PFAS in a controlled and predictable way into benign products. By understanding the fate of these compounds during thermal decomposition, the project will allow the development of a new technology aimed at treating materials which have been contaminated with or have been used as absorbants for PFAS. The project will provide the technical underpinning of a new technology developed to treat fluorochemical-contaminated material and, in doing so, reduce the environmental impact of these contaminants.Read moreRead less
Biochar as a renewable catalyst for hot gas cleaning. This project aims to generate new knowledge for the development of a novel hot gas cleaning technology. This project expects to understand the mechanisms of tar reforming using biochar as a renewable catalyst, which can avoid the problems associated with the catalyst deactivation and catalyst disposal if conventional supported catalysts are used. Expected outcomes of this project include a theoretical framework and a kinetic model describing ....Biochar as a renewable catalyst for hot gas cleaning. This project aims to generate new knowledge for the development of a novel hot gas cleaning technology. This project expects to understand the mechanisms of tar reforming using biochar as a renewable catalyst, which can avoid the problems associated with the catalyst deactivation and catalyst disposal if conventional supported catalysts are used. Expected outcomes of this project include a theoretical framework and a kinetic model describing the catalytic reforming of tar as part of the hot gas cleaning during the conversion of biomass. The technology will contribute to Australia’s improved energy security and reduced carbon dioxide (CO2) emissions in the carbon-constrained future.Read moreRead less
Catalytic Degardation of Emerging Microplastic Pollutants. This project aims to develop robust and low-cost nanocarbon hybrids and advanced remediation technology to address globally emerging microplastic contaminations. The project expects to boost innovations in development of novel magnetic nanomaterials, process of microplastic purification, and green catalysis. Expected outcomes of this project will include efficient strategies in materials fabrication and a cutting-edge nanotechnology. The ....Catalytic Degardation of Emerging Microplastic Pollutants. This project aims to develop robust and low-cost nanocarbon hybrids and advanced remediation technology to address globally emerging microplastic contaminations. The project expects to boost innovations in development of novel magnetic nanomaterials, process of microplastic purification, and green catalysis. Expected outcomes of this project will include efficient strategies in materials fabrication and a cutting-edge nanotechnology. The success of the project will underpin the scientific bases of carbocatalysis, provide significant benefits to the Australian industry and society for a sustainable future with clean water, and increase the leading capacity of Australia in fundamental research and frontier technology.Read moreRead less
3-D Printed Catalytic Monoliths for Energy Efficient Carbon Conversion. Carbon Capture and Utilisation (CCU) is an essential pathway for reducing carbon in the Earth's atmosphere. However a major hurdle in the carbon utilisation part is that the conversion technologies often rely on energy derived from fossil sources. Electrification of carbon conversion processes can overcome this hurdle by providing this energy via renewables. This project aims to develop an electrically powered energy efficie ....3-D Printed Catalytic Monoliths for Energy Efficient Carbon Conversion. Carbon Capture and Utilisation (CCU) is an essential pathway for reducing carbon in the Earth's atmosphere. However a major hurdle in the carbon utilisation part is that the conversion technologies often rely on energy derived from fossil sources. Electrification of carbon conversion processes can overcome this hurdle by providing this energy via renewables. This project aims to develop an electrically powered energy efficient catalytic process for carbon conversion. A modular 3-D printed monolithic catalytic reactor prototype powered by induction or resistive heating will be developed to minimise energy loss in the carbon conversion process. An expected outcome of this project is translation of this prototype in a CCU pilot scale facility.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100253
Funder
Australian Research Council
Funding Amount
$450,948.00
Summary
Functional carbon hybrids for green catalysis and clean water. This project aims to develop a family of structure-tailored, robust and metal-free carbon hybrids and environmental-benign processes for catalytic degradation of emerging microcontaminants in water. Innovations are expected in the design of reaction-oriented nanocarbons, new concept in atomic level carbocatalysis from computation and in-situ characterisation, advanced purification technology, and breakthroughs in material engineering ....Functional carbon hybrids for green catalysis and clean water. This project aims to develop a family of structure-tailored, robust and metal-free carbon hybrids and environmental-benign processes for catalytic degradation of emerging microcontaminants in water. Innovations are expected in the design of reaction-oriented nanocarbons, new concept in atomic level carbocatalysis from computation and in-situ characterisation, advanced purification technology, and breakthroughs in material engineering. The anticipated outcomes will be the scientific basis for functional nanomaterials, nanotechnology, and green remediation technologies. Success will provide significant benefits in securing a sustainable future for Australia, with clean water and strategies for advanced manufacturing in related areas. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220101074
Funder
Australian Research Council
Funding Amount
$424,500.00
Summary
Conversion of biowastes to porous carbon materials for green catalysis. This project aims to develop a family of biowaste-derived porous carbon and single-atom-anchored porous carbon catalysts for the degradation of emerging microcontaminants in water. Innovations are expected in systematically developing affordable, facile, productive, and sustainable approaches. Via reaction-oriented structure design, new concept will be defined at the atomic level using calculations and in situ characterisati ....Conversion of biowastes to porous carbon materials for green catalysis. This project aims to develop a family of biowaste-derived porous carbon and single-atom-anchored porous carbon catalysts for the degradation of emerging microcontaminants in water. Innovations are expected in systematically developing affordable, facile, productive, and sustainable approaches. Via reaction-oriented structure design, new concept will be defined at the atomic level using calculations and in situ characterisations in material engineering and advanced purification technology. The anticipated outcomes will provide fundamental knowledge in green nanotechnologies for water remediation. Success will secure a sustainable future for Australia with clean water and strategies for advanced manufacturing in relevant areas.Read moreRead less
Unlocking Australia's offshore gas endowment. This project aims to develop practical new methods of predicting and detecting the formation of solids in gas and liquefied natural gas (LNG) production. Australia has large offshore reserves of natural gas and has made the investments necessary to help fuel the global transition to cleaner, reliable energy sources. However, conventional engineering approaches of producing gas from deep-water reserves have reached the limits of viability because of t ....Unlocking Australia's offshore gas endowment. This project aims to develop practical new methods of predicting and detecting the formation of solids in gas and liquefied natural gas (LNG) production. Australia has large offshore reserves of natural gas and has made the investments necessary to help fuel the global transition to cleaner, reliable energy sources. However, conventional engineering approaches of producing gas from deep-water reserves have reached the limits of viability because of the costs required to prevent solids forming in subsea pipelines or cryogenic LNG plants. The project’s expected outcome include sophisticated tools in open-access software based on these new predictive methods, and a step-change in Australia’s ability to access its offshore gas.Read moreRead less
Catalytic conversion of Australia's natural gas to value added products. While natural gas (of which methane is the primary component) is an abundant source of energy, it is normally found in remote areas and for its successful exploitation it needs to be processed. The processing usually requires significant energy and resources input. In this project we will develop a fundamental understanding to a single step catalytic process that can utilise natural gas and nitrous oxide (both potent greenh ....Catalytic conversion of Australia's natural gas to value added products. While natural gas (of which methane is the primary component) is an abundant source of energy, it is normally found in remote areas and for its successful exploitation it needs to be processed. The processing usually requires significant energy and resources input. In this project we will develop a fundamental understanding to a single step catalytic process that can utilise natural gas and nitrous oxide (both potent greenhouse gases) and oxygen to produce selectively methanol and hydrocarbons from a natural gas feedstream in a controlled manner. A single step process for natural gas conversion utilising waste green-house gases is expected to be of great benefit to the Australian economy, environment and energy securityRead moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100429
Funder
Australian Research Council
Funding Amount
$406,177.00
Summary
Bioinspired Photocatalysts for Solar-Driven Hydrogen Peroxide Production. This project aims to develop advanced photocatalysts that can efficiently produce hydrogen peroxide from just water, air, and sunlight. By mimicking the structure and function of the natural photosynthetic apparatus, the key innovations are expected in the design of reaction-oriented conjugated polymer-based photocatalysts at the atomic and molecular nanostructure levels. It expects to generate new knowledge in artificial ....Bioinspired Photocatalysts for Solar-Driven Hydrogen Peroxide Production. This project aims to develop advanced photocatalysts that can efficiently produce hydrogen peroxide from just water, air, and sunlight. By mimicking the structure and function of the natural photosynthetic apparatus, the key innovations are expected in the design of reaction-oriented conjugated polymer-based photocatalysts at the atomic and molecular nanostructure levels. It expects to generate new knowledge in artificial photosynthesis and rational design of functional materials, and sustainable technology for hydrogen peroxide production. This cross-disciplinary research will benefit Australia by the development of biomimetic catalysts for advancing solar energy conversion and enabling sustainable manufacturing of commodity chemicals. Read moreRead less
Controllable Synthesis of Defects in Catalysts for Electrocatalysis . This project aims to address the most critical issue of electrocatalysis: identification of active sites for carbon-based metal free catalysts (CMFCs). Through the development of new methodologies, this proposal will, for the first time, controllably synthesise the vacancy defects that are the major active sites for CMFCs. The expected outcomes from this project include in-depth understanding of the fundamentals of electrocata ....Controllable Synthesis of Defects in Catalysts for Electrocatalysis . This project aims to address the most critical issue of electrocatalysis: identification of active sites for carbon-based metal free catalysts (CMFCs). Through the development of new methodologies, this proposal will, for the first time, controllably synthesise the vacancy defects that are the major active sites for CMFCs. The expected outcomes from this project include in-depth understanding of the fundamentals of electrocatalysis: the reactivity of active sites and the catalytic performance with the number of active sites; which will not only significantly advance knowledge but also achieve breakthrough technologies that greatly benefit to the society and economy both for Australia and worldwide.Read moreRead less