Hydrogen Production by Non-thermal Plasma Assisted Catalytic Pyrolysis of Natural Gas. This project aims to develop a cost effective technology for hydrogen production using catalytic pyrolysis of natural gas assisted by non-thermal plasma. The mechanism and kinetics of catalytic hydrocarbon decomposition on carbons produced in situ will be systematically studied. Based on the fundamental understanding of carbon nanostructures and their catalytic activities and stabilities, the non-thermal plasm ....Hydrogen Production by Non-thermal Plasma Assisted Catalytic Pyrolysis of Natural Gas. This project aims to develop a cost effective technology for hydrogen production using catalytic pyrolysis of natural gas assisted by non-thermal plasma. The mechanism and kinetics of catalytic hydrocarbon decomposition on carbons produced in situ will be systematically studied. Based on the fundamental understanding of carbon nanostructures and their catalytic activities and stabilities, the non-thermal plasma and the catalytic reactions will be optimized to achieve high conversion and catalytic stability. The project will lead to a new process combining effective carbon catalyst and low temperature plasma to produce pure hydrogen with high energy efficiency and no CO2 emissions.Read moreRead less
Production of hydrogen from biomass by integrated catalytic aqueous hydrolysis and reforming in subcritical water. The outcomes of this project will lead to the development of a novel process for efficient and cost-effective hydrogen production from renewable biomass using integrated hydrolysis and catalytic aqueous reforming at low temperatures. Such technological innovation will provide significant benefits to Australia as a whole for transition to a truly sustainable hydrogen economy. The nov ....Production of hydrogen from biomass by integrated catalytic aqueous hydrolysis and reforming in subcritical water. The outcomes of this project will lead to the development of a novel process for efficient and cost-effective hydrogen production from renewable biomass using integrated hydrolysis and catalytic aqueous reforming at low temperatures. Such technological innovation will provide significant benefits to Australia as a whole for transition to a truly sustainable hydrogen economy. The novel reaction system and research methodologies proposed in this proposal will certainly enhance Australia's science and technology capability and international competitiveness, in the area of reaction engineering. Also of the national benefit is the successful training of a postgraduate at PhD level who will no doubt add to future scientific research workforce.Read moreRead less
Methane Coupling Using Mixed Conducting Catalytic Ceramic Hollow Fibre Membrane Reactor. The Gas product industry is one of the most important economic sectors in Australia, employing 10000 people with market value of $ 100 billion per year from power generation and LNG export. However, there are increasing concerns over issues of the green house gases emission and petroleum dwindling. This project addresses the technology needs in converting natural gas to more useful chemicals via a more effic ....Methane Coupling Using Mixed Conducting Catalytic Ceramic Hollow Fibre Membrane Reactor. The Gas product industry is one of the most important economic sectors in Australia, employing 10000 people with market value of $ 100 billion per year from power generation and LNG export. However, there are increasing concerns over issues of the green house gases emission and petroleum dwindling. This project addresses the technology needs in converting natural gas to more useful chemicals via a more efficient and cleaner means of methane utilization. The project target is to make the natural gas resources in Australia to delivery high value products with considerable economic benefits and increased employment opportunities. Read moreRead less
Low-temperature plasma-catalytic conversion of CH4 and CO2 to alcohols. This project aims to investigate a novel concept of integrated low-temperature plasma and catalytic membrane hybrid reactor system for alcohols production from methane (CH4), carbon dioxide (CO2) and water vapour. This research will combine plasma physics and reaction engineering techniques to develop an innovative gas to liquid technology. The outcomes have the potential to transform the nation's natural gas industry, impro ....Low-temperature plasma-catalytic conversion of CH4 and CO2 to alcohols. This project aims to investigate a novel concept of integrated low-temperature plasma and catalytic membrane hybrid reactor system for alcohols production from methane (CH4), carbon dioxide (CO2) and water vapour. This research will combine plasma physics and reaction engineering techniques to develop an innovative gas to liquid technology. The outcomes have the potential to transform the nation's natural gas industry, improve energy efficiency, and utilise CO2 rich gas resources.Read moreRead less
A green technology for liquefied natural gas (LNG) regasification. Upon arrival to its destination, the liquefied natural gas (LNG) exported from Australia must be converted back into gas to make it suitable for distribution to end users, for which the current technologies burn up to two per cent our LNG exports. This project will design a technology that will use the energy of ambient air, which will not only increase the profit but also reduce carbon dioxide emissions.
Discovery Early Career Researcher Award - Grant ID: DE130101215
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
A novel pyrolysis process for high-quality bio-oil production from biomass. The project outcome will provide fundamental knowledge essential to the development of a novel pyrolysis process for high-quality bio-oil production with biochar, a value-added by-product. It will largely accelerate the commercialisation of the biomass pyrolysis process to reduce greenhouse gas emissions and fossil fuel use in the energy sector.
Advanced biomass gasification process for distributed power generation with significant negative carbon emission in rural and regional Australia. The outcome of this project is fundamental knowledge essential to the development of advanced biomass gasification processes for distributed power generation with drastic reduction in carbon emissions and the recycling of inorganic nutrients to the land. It will contribute significantly to the future sustainability of rural and regional Australia.
Integrated photo and thermal catalysis for economic carbon dioxide conversion to fuels. The project aims to develop an integrated process for simultaneously photo- and thermal-catalytic conversion of carbon dioxide and water vapour to hydrocarbon fuels and chemicals using solar light and waste heat from flue gas. This project will design and make multi-functional catalysts based on zirconium metal organic frameworks, incorporating quantum dots and metal nanoclusters. This project is expected to ....Integrated photo and thermal catalysis for economic carbon dioxide conversion to fuels. The project aims to develop an integrated process for simultaneously photo- and thermal-catalytic conversion of carbon dioxide and water vapour to hydrocarbon fuels and chemicals using solar light and waste heat from flue gas. This project will design and make multi-functional catalysts based on zirconium metal organic frameworks, incorporating quantum dots and metal nanoclusters. This project is expected to develop an advanced materials system, reduce carbon dioxide and use it to produce fuel, and harness solar energy. The project should advance Australia’s leading role in reducing carbon emission, and producing clean energy and nanotechnology.Read moreRead less
Coarse-Grid Eulerian-Eulerian Multiphase Model for Fluid Catalytic Cracking Unit. A fluid catalytic cracking (FCC) unit is an important refinery unit operation responsible for about 45% of total petrol production. The aim of this study is to improve the petrol production efficiency of Australian refineries thus allowing our country not only to maintain its self-sufficiency but also to permit lucrative exports. This will be done by optimising the performance of the FCC unit through novel computat ....Coarse-Grid Eulerian-Eulerian Multiphase Model for Fluid Catalytic Cracking Unit. A fluid catalytic cracking (FCC) unit is an important refinery unit operation responsible for about 45% of total petrol production. The aim of this study is to improve the petrol production efficiency of Australian refineries thus allowing our country not only to maintain its self-sufficiency but also to permit lucrative exports. This will be done by optimising the performance of the FCC unit through novel computational fluid dynamic simulations. The outcomes of this study will enable refiners to produce cleaner fuel (e.g., fuel with less sulphur) and decrease air pollution from the FCC unit (in the form of CO and particulates) thus helping Australia to preserve its diverse and relatively pollution-free environment.Read moreRead less
Near zero-emission hydrogen and carbon production from natural gas and bio-methane. Hydrogen is envisaged as a clean fuel for power generation particularly for the transportation sector. In the short- and mid-term future, hydrogen will be derived from fossil fuels. Based on the conventional processes, the route from fossil fuels to hydrogen invariably produces greenhouse gases. Geosequestration is a viable technique of storing carbon dioxide but has an uncertain long-term environmental ramifi ....Near zero-emission hydrogen and carbon production from natural gas and bio-methane. Hydrogen is envisaged as a clean fuel for power generation particularly for the transportation sector. In the short- and mid-term future, hydrogen will be derived from fossil fuels. Based on the conventional processes, the route from fossil fuels to hydrogen invariably produces greenhouse gases. Geosequestration is a viable technique of storing carbon dioxide but has an uncertain long-term environmental ramification. In contrast, our proposed technique avoids the production of greenhouse gases and, instead, engenders high value added graphitized carbon as a by-product. Given the relative stability and value of graphitized carbon, our catalytic cracking process provides another option to geosequestration.Read moreRead less