In-situ catalytic upgrading of bio-oil using scrap tyre char. This project aims to develop advanced, cost-competitive catalysts based on scrap tyre char, an otherwise low-value by-product. These catalysts will be optimised for use in upgrading bio-oil derived from the pyrolysis of woody eucalyptus, an abundant biomass resource across Australia. The project is expected to promote the commercialisation of bio-oil production and enhance the valorisation of scrap tyre char. This is expected to reduc ....In-situ catalytic upgrading of bio-oil using scrap tyre char. This project aims to develop advanced, cost-competitive catalysts based on scrap tyre char, an otherwise low-value by-product. These catalysts will be optimised for use in upgrading bio-oil derived from the pyrolysis of woody eucalyptus, an abundant biomass resource across Australia. The project is expected to promote the commercialisation of bio-oil production and enhance the valorisation of scrap tyre char. This is expected to reduce the carbon footprint from Australian industry, and promote the recycling and reuse of waste scrap tyres.Read moreRead less
Syngas Production Using Catalytic Carbon Dioxide Dry Reforming. This project intends to pave the way for turning remote low-value Australian resources and greenhouse gases into valuable products. Most of Australian natural gas reserves are located in the remote north-west shelf, and many are small scale and thus cannot be economically harnessed using conventional methods such as pipeline transportation or gas liquefaction. In this project, a dry reforming reactor with novel catalysts will be des ....Syngas Production Using Catalytic Carbon Dioxide Dry Reforming. This project intends to pave the way for turning remote low-value Australian resources and greenhouse gases into valuable products. Most of Australian natural gas reserves are located in the remote north-west shelf, and many are small scale and thus cannot be economically harnessed using conventional methods such as pipeline transportation or gas liquefaction. In this project, a dry reforming reactor with novel catalysts will be designed for converting natural gas and carbon dioxide to syngas, which is an intermediate step of gas-to-liquid plant. By innovatively integrating advanced catalysis and heating technologies, reactor weight and operational costs will be minimised.Read moreRead less
Methanol to diesel. Australia has large remote gas reserves which are not accessible to markets via pipeline and cannot be effectively utilised using liquefied natural gas technology. Fischer-Tropsch conversion of gas to liquid (GTL), being capital intense, is uneconomical for these stranded gas resources. This project will develop a new GTL technology to produce sulphur-free, clean combustion diesel. The outcomes of this research will be a frontier technology that allows more effective utilisat ....Methanol to diesel. Australia has large remote gas reserves which are not accessible to markets via pipeline and cannot be effectively utilised using liquefied natural gas technology. Fischer-Tropsch conversion of gas to liquid (GTL), being capital intense, is uneconomical for these stranded gas resources. This project will develop a new GTL technology to produce sulphur-free, clean combustion diesel. The outcomes of this research will be a frontier technology that allows more effective utilisation of Australian remote gas resources to meet rising global demand for transport fuels, adding enormous value to Australian natural resources and contributing to Building and Transforming Australian industries.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