A defect mechanism for oxygen reduction reaction. This project aims to use defective carbon to replace expensive platinum as a catalyst for oxygen reduction reaction (ORR) in fuel cells. Defective carbons incorporating non-precious metals are better than platinum in terms of over-potential, current density and number of electron transfer. They reduce the overall fuel cell cost but their better stability and higher open voltage and power density promise huge commercial benefit. This project is ex ....A defect mechanism for oxygen reduction reaction. This project aims to use defective carbon to replace expensive platinum as a catalyst for oxygen reduction reaction (ORR) in fuel cells. Defective carbons incorporating non-precious metals are better than platinum in terms of over-potential, current density and number of electron transfer. They reduce the overall fuel cell cost but their better stability and higher open voltage and power density promise huge commercial benefit. This project is expected to be important for large-scale implementation of fuel cells.Read moreRead less
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
Engineering the Building Blocks of Novel Interfacial Metastable Oxide Materials. This project aims to engineer the building blocks of a new family of materials recently discovered and patented as interfacial metastable oxide (i-MOx). A key discovery is the interfacial columnar atom alignment adjacent to crystal structures, conferring the materials exceptional ionic conduction well beyond the state-of-the-art, with a broad appeal to ionic transport membranes, electrodes in fuel cells and thermal ....Engineering the Building Blocks of Novel Interfacial Metastable Oxide Materials. This project aims to engineer the building blocks of a new family of materials recently discovered and patented as interfacial metastable oxide (i-MOx). A key discovery is the interfacial columnar atom alignment adjacent to crystal structures, conferring the materials exceptional ionic conduction well beyond the state-of-the-art, with a broad appeal to ionic transport membranes, electrodes in fuel cells and thermal cycling oxygen production. Advanced characterisation techniques will be employed to fundamentally elucidate the role that the interfacial structure plays to deliver remarkable performance. The outcomes will lead to possible breakthroughs in advanced materials for emerging green energy applications.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
Scale up of direct carbon fuel cells. As a modern society, Australia is highly reliant on energy which is derived predominantly from coal using pulverised fuel technology with low efficiency (35-40 per cent) and high greenhouse gas emissions. This project will develop a new method for the more efficient utilisation of Australia's coals. Consequently, the power generation industry in Australia will be able to export energy in the 80 per cent efficiency range, while pure carbon dioxide can be easi ....Scale up of direct carbon fuel cells. As a modern society, Australia is highly reliant on energy which is derived predominantly from coal using pulverised fuel technology with low efficiency (35-40 per cent) and high greenhouse gas emissions. This project will develop a new method for the more efficient utilisation of Australia's coals. Consequently, the power generation industry in Australia will be able to export energy in the 80 per cent efficiency range, while pure carbon dioxide can be easily sequestrated.Read moreRead less
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
Industrial Transformation Training Centres - Grant ID: IC150100019
Funder
Australian Research Council
Funding Amount
$4,571,797.00
Summary
ARC Training Centre for Liquefied Natural Gas Futures. ARC Training Centre for Liquefied Natural Gas Futures. This training centre aims to deliver projects and training to enable future Australian Liquefied Natural Gas (LNG) production from reserves in deep water, at small or remote on-shore locations, with greater efficiency, less environmental impact, and at lower cost than currently possible. This should be accomplished via research projects undertaken by the PhD students and research fellows ....ARC Training Centre for Liquefied Natural Gas Futures. ARC Training Centre for Liquefied Natural Gas Futures. This training centre aims to deliver projects and training to enable future Australian Liquefied Natural Gas (LNG) production from reserves in deep water, at small or remote on-shore locations, with greater efficiency, less environmental impact, and at lower cost than currently possible. This should be accomplished via research projects undertaken by the PhD students and research fellows with guidance from the centre’s industrial partners. The centre’s expected legacy is a unique research and training facility, designed for future integration into a microscale LNG plant. The anticipated research and training outcomes will help to ensure Australia plays a leading role in future global LNG developments.Read moreRead less
Mudstones as methane sources: gas production from coal seam interburden. Carbonaceous mudstones associated with coal measures already exploited for gas present an attractive reservoir of methane. This project seeks to provide methods for accessing this gas. Mudstone associated with coal seam gas developments are very extensive and gas quantities may exceed even that in the coal itself. Further infrastructure and access permits are already in place for coal seam gas recovery. Unlike shale, which ....Mudstones as methane sources: gas production from coal seam interburden. Carbonaceous mudstones associated with coal measures already exploited for gas present an attractive reservoir of methane. This project seeks to provide methods for accessing this gas. Mudstone associated with coal seam gas developments are very extensive and gas quantities may exceed even that in the coal itself. Further infrastructure and access permits are already in place for coal seam gas recovery. Unlike shale, which is fissile, mudstone is much softer, more malleable and plastic, and consequently will respond abnormally to hydraulic fracturing and propping, so new methods proposed to be developed in this project are needed for stimulation.Read moreRead less
Characterisation and Treatment of Reverse Osmosis Concentrates from Water Recycling Applications. Concentrates from reverse osmosis (RO) pose a considerable threat to both the environment but also the successful implementation of reverse osmosis as a technology. Naturally, the concentrate contains everything that the RO retains and hence contaminants such as viruses, organics such as pharmaceutically active compounds and hormones as well as nutrients and salinity. Treatment of such waste streams ....Characterisation and Treatment of Reverse Osmosis Concentrates from Water Recycling Applications. Concentrates from reverse osmosis (RO) pose a considerable threat to both the environment but also the successful implementation of reverse osmosis as a technology. Naturally, the concentrate contains everything that the RO retains and hence contaminants such as viruses, organics such as pharmaceutically active compounds and hormones as well as nutrients and salinity. Treatment of such waste streams will enhance the health of receiving water bodies and reduce the risk of increased build up of contaminants if wastes are recycled into wastewater treatment plants. New ways to treat such contaminants will be explored, the efficiency and cost evaluated in the broader water cycle and sustainability framework.Read moreRead less
Ozone-Enhanced Particle Removal in Water Treatment. Combined ozonation/biologically active carbon filtration provides effective contaminant removal while minimizing disinfection by-product formation. However, the cost of installation in conventional water treatment plants is very high. This project will investigate the beneficial influence of ozonation on the micro-flocculation of small particles, with the aim to optimising particle removal by sedimentation prior to filtration. To do this, requi ....Ozone-Enhanced Particle Removal in Water Treatment. Combined ozonation/biologically active carbon filtration provides effective contaminant removal while minimizing disinfection by-product formation. However, the cost of installation in conventional water treatment plants is very high. This project will investigate the beneficial influence of ozonation on the micro-flocculation of small particles, with the aim to optimising particle removal by sedimentation prior to filtration. To do this, requires a clear understanding of how dissolved ozone interacts with particle surfaces for different water chemistries. The ideal outcome would be to develop a robust water treatment system that required BAC filtration only and eliminated the need for a conventional sand filtration stage as well.Read moreRead less