Membrane distillation development for concentrated solar thermal systems. Membrane distillation development for concentrated solar thermal systems. This project aims to develop a new membrane distillation module that works with a high efficiency solar thermal tower system. Fresh water and energy are inextricably linked and form the basis for all human activity. Remote locations in Australia and the Middle East and North Africa are blessed with abundant solar resources and increasing levels of de ....Membrane distillation development for concentrated solar thermal systems. Membrane distillation development for concentrated solar thermal systems. This project aims to develop a new membrane distillation module that works with a high efficiency solar thermal tower system. Fresh water and energy are inextricably linked and form the basis for all human activity. Remote locations in Australia and the Middle East and North Africa are blessed with abundant solar resources and increasing levels of development, but burdened by access to reliable water treatment and electricity generation facilities. This project will use recently developed materials and design tools to overcome technical challenges that limited membrane distillation technology. This is expected to open up an innovative method for co-production of water and electricity which can handle transient solar and water quality inputs.Read moreRead less
Doped Nanocrystalline TiO2 - Synthesis and application for photoreduction reactions. The proposed project aims to develop a novel photocatalyst, prepared by doping nanocrystalline TiO2 with noble metals, for use in photoreduction reactions. The ability of this photocatalyst to reduce heavy metals and its potential to generate H2 in an inert environment will be explored. The project will benefit the environment by removing toxic compounds from polluted wastewaters as well as potentially generatin ....Doped Nanocrystalline TiO2 - Synthesis and application for photoreduction reactions. The proposed project aims to develop a novel photocatalyst, prepared by doping nanocrystalline TiO2 with noble metals, for use in photoreduction reactions. The ability of this photocatalyst to reduce heavy metals and its potential to generate H2 in an inert environment will be explored. The project will benefit the environment by removing toxic compounds from polluted wastewaters as well as potentially generating substantial levels of H2 (an attractive energy source). Project outcomes include the development of an economical and cleaner process for treating waters contaminated with heavy metals and providing a valuable knowledge base from which photoreductive efficiencies can be drawn.Read moreRead less
Innovative High Temperature Carbon–Air Batteries for High Power Generation. The project intends to develop carbon-air batteries which are expected to have energy density 10 times that of lithium-ion batteries. The battery is designed to use naturally-rich carbon as fuel, highly energy-efficient solid oxide fuel cells as electrochemical reactors, and an integrated mixed conducting ceramic membrane for in situ carbon dioxide separation. The success of this project would provide us with a low-carbo ....Innovative High Temperature Carbon–Air Batteries for High Power Generation. The project intends to develop carbon-air batteries which are expected to have energy density 10 times that of lithium-ion batteries. The battery is designed to use naturally-rich carbon as fuel, highly energy-efficient solid oxide fuel cells as electrochemical reactors, and an integrated mixed conducting ceramic membrane for in situ carbon dioxide separation. The success of this project would provide us with a low-carbon energy system based on Australia’s rich coal resources. New knowledge about carbon dioxide separation may also facilitate carbon dioxide sequestration in other fields.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100523
Funder
Australian Research Council
Funding Amount
$359,446.00
Summary
Tailoring efficient photo-thermal catalysts for carbon dioxide reduction. This project aims to develop a highly solar-efficient and environmentally-friendly approach to reducing greenhouse gas carbon dioxide (CO2) into valuable fuels that will be beneficial for relieving energy shortage and improving global sustainability. New multifunctional catalysts will be constructed by combining various catalytic active centres and optical promoters, for optimising energy efficiency and reaction activity. ....Tailoring efficient photo-thermal catalysts for carbon dioxide reduction. This project aims to develop a highly solar-efficient and environmentally-friendly approach to reducing greenhouse gas carbon dioxide (CO2) into valuable fuels that will be beneficial for relieving energy shortage and improving global sustainability. New multifunctional catalysts will be constructed by combining various catalytic active centres and optical promoters, for optimising energy efficiency and reaction activity. Such knowledge gained is essential for the success of the low-carbon industry and a more environmentally-friendly energy economy in Australia.Read moreRead less
Solar-driven massive hydrogen production from biomass and biomass/coal mixtures by supercritical water gasification. Cheap and massive hydrogen production from renewable resources is one of the key challenges to achieve a hydrogen economy that promises to ultimately solve critical problems, such as energy depletion and climate change. This project exactly falls into this research and development priority and will benefit Australian economy and environment.
Highly efficient electric power and value-added synthesis gas co-generation from methane with zero greenhouse gas emission. This project addresses a novel sealing-free solid oxide fuel cell system producing simultaneously synthesis gas and electricity from methane with zero greenhouse gas emission. The project aims to deliver economic benefits and contribute to environmental protection and increased employment opportunities.
Optical fibre photoreactor for removing airborne molecular contaminants and volatile organic carbons for semiconductor fabrication and fuel cell applications. The collaboration integrates concepts from photocatalysis, optical fibre technology and filtration, to solve important issues in the semiconductor fabrication and fuel cell industries. The project will place Australia amongst the world-leaders in novel integrated photocatalytic/filtration techniques and provide significant opportunities fo ....Optical fibre photoreactor for removing airborne molecular contaminants and volatile organic carbons for semiconductor fabrication and fuel cell applications. The collaboration integrates concepts from photocatalysis, optical fibre technology and filtration, to solve important issues in the semiconductor fabrication and fuel cell industries. The project will place Australia amongst the world-leaders in novel integrated photocatalytic/filtration techniques and provide significant opportunities for penetration, in particular, into the US filtration market. The collaboration will afford young Australian-based researchers the opportunity to access technology, expertise and knowledge developed in the US, which is currently unavailable in Australia. It will strengthen ties between UNSW and UMN and provide opportunities for further collaboration.Read moreRead less
Optical tweezers as a micro-rheological probe of soft surfaces. Biomembranes are more than soft containers - their dynamic flexibility plays an important role in cell function, but measurements of mechanical properties of soft surfaces are non-existent. This project develops and applies a new optical tweezers method to measure the flexibility of membranes and its effects upon the friction of nearby particles.
University of Queensland/Arizona State University partnership to design industrially suitable zeolite membranes for desalination. For desalination, the highest costs are organic-based membrane replacement (lasting ~1 year) and energy requirement. Functionalised zeolitic membranes are low-cost, high performing, chemically tolerant and thermally stable. New zeolite membranes in principle could perform the separation outlasting their organic counterparts, while at the same time offering major energ ....University of Queensland/Arizona State University partnership to design industrially suitable zeolite membranes for desalination. For desalination, the highest costs are organic-based membrane replacement (lasting ~1 year) and energy requirement. Functionalised zeolitic membranes are low-cost, high performing, chemically tolerant and thermally stable. New zeolite membranes in principle could perform the separation outlasting their organic counterparts, while at the same time offering major energy reductions from higher fluxes. Current zeolite membrane research for desalination however is lacking. The proposed team offers experience in bringing highly significant lab scale technologies to industrial scales. The outcomes will address mutual priorities between Australia and USA for reliable low cost supply of fresh water.Read moreRead less
Adsorption and Removal of Trace Organic Compounds by Membrane Processes used in Water Treatment and Wastewater Recycling. Recycling of municipal wastewaters is of growing importance as a resource-conservation and environmental-protection measure in Australia. A major impediment to increased rates of water recycling is a lack of knowledge regarding the presence, fate and removal of key trace organic compounds. Among these key contaminants are pharmaceutically active compounds (PhACs) and steroid ....Adsorption and Removal of Trace Organic Compounds by Membrane Processes used in Water Treatment and Wastewater Recycling. Recycling of municipal wastewaters is of growing importance as a resource-conservation and environmental-protection measure in Australia. A major impediment to increased rates of water recycling is a lack of knowledge regarding the presence, fate and removal of key trace organic compounds. Among these key contaminants are pharmaceutically active compounds (PhACs) and steroid hormones. This research will lead to a thorough understanding of the mechanisms involved with the removal of these compounds by membrane treatment applications. Major benefits will be enhanced ability to undertake risk management and a lowering of costs associated with full-scale water treatment applications.Read moreRead less