Smart utilisation of cobaltite based electrodes on solid oxide fuel cells. This project aims to develop solid oxide fuel cell technologies with significantly simplified fabrication steps and at low cost. It aims to generate fundamental knowledge on the polarisation induced electrode/electrolyte interfaces under fuel cell operation conditions. The advanced fuel cell technologies will in turn substantially increase the energy conversion efficiency and provide significant benefit in the reduction o ....Smart utilisation of cobaltite based electrodes on solid oxide fuel cells. This project aims to develop solid oxide fuel cell technologies with significantly simplified fabrication steps and at low cost. It aims to generate fundamental knowledge on the polarisation induced electrode/electrolyte interfaces under fuel cell operation conditions. The advanced fuel cell technologies will in turn substantially increase the energy conversion efficiency and provide significant benefit in the reduction of greenhouse emission.Read moreRead less
Single-atom catalysts for electrochemical carbon dioxide conversion. This project aims to develop a new synthetic technique for the fabrication of template-free and metal single-atoms embedded in doped carbon nano tubes. It will generate fundamental knowledge about multiple proton and electron transfer steps in carbon dioxide (CO2RR) using in-situ synchrotron characterisation techniques. Expected outcomes of the research include the development of new single-atom catalysts for production of the ....Single-atom catalysts for electrochemical carbon dioxide conversion. This project aims to develop a new synthetic technique for the fabrication of template-free and metal single-atoms embedded in doped carbon nano tubes. It will generate fundamental knowledge about multiple proton and electron transfer steps in carbon dioxide (CO2RR) using in-situ synchrotron characterisation techniques. Expected outcomes of the research include the development of new single-atom catalysts for production of the key feed-stock of CO for sustainable use in hydrocarbon fuels, providing significant benefits in the reduction of greenhouse emissions.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101824
Funder
Australian Research Council
Funding Amount
$376,970.00
Summary
Capturing Latent Methane Emissions from Natural Gas Production. Methane is 21 times more potent than carbon dioxide as a greenhouse gas. The natural gas industry produces significant methane emissions through collateral venting with nitrogen gas. Recovering waste methane will reduce greenhouse gas emissions and increase the revenue of natural gas processors. This project will develop the technology needed to capture the latent methane and significantly reduce its concentration in nitrogen gas ri ....Capturing Latent Methane Emissions from Natural Gas Production. Methane is 21 times more potent than carbon dioxide as a greenhouse gas. The natural gas industry produces significant methane emissions through collateral venting with nitrogen gas. Recovering waste methane will reduce greenhouse gas emissions and increase the revenue of natural gas processors. This project will develop the technology needed to capture the latent methane and significantly reduce its concentration in nitrogen gas rich vent streams. New adsorbents for separating these gases, such as molecular trapdoor zeolites, will be designed and tested over wide ranges of pressure and temperature. Dual reflux pressure swing adsorption cycles will be tested using the best materials to demonstrate how latent methane emissions can be reduced to part-per-million levels.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100036
Funder
Australian Research Council
Funding Amount
$950,000.00
Summary
A customised triple-beam microscope for precise fabricating/characterising . This project aims to establish a customised triple-beam microscope to enable precise fabrication and polishing (using ion beams) and characterisation (using electron beam) of a wide range of advanced materials. It will provide solutions to prepare ultra-high quality and artefact-free specimens for transmission electron microscopy studies, and allow fabrication of unique nanostructures and nanostructured templates for hi ....A customised triple-beam microscope for precise fabricating/characterising . This project aims to establish a customised triple-beam microscope to enable precise fabrication and polishing (using ion beams) and characterisation (using electron beam) of a wide range of advanced materials. It will provide solutions to prepare ultra-high quality and artefact-free specimens for transmission electron microscopy studies, and allow fabrication of unique nanostructures and nanostructured templates for high-performance applications. The customised features of the proposed instrument are the first of its kind in Australia. The new knowledge developed through this project will significantly impact on scientific insights and practical applications of new materials related to physics, chemistry, biology, geology and engineering.Read moreRead less
Highly ordered and tuneable mesostructured perfluorosulfonic acid polymers as novel proton exchange membranes for fuel cells. The purpose of the project is to develop an innovative perfluorofonic acid based proton exchange membranes (PEM) with ordered and tuneable mesopores and it is expected that PEM fuel cell power systems based on such new PEMs will have significant impact on the advancement of fuel cell technologies and the reduction in greenhouse gas emission.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100208
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
An advanced computational facility based on a graphic processing unit for particulate research. The graphic processing unit (GPU) is becoming an engine for the next generation of supercomputers for scientific research. The technology at this new facility will be exploited to perform large-scale, real time simulations of complex particulate material processing which is critical to Australia’s mineral/metallurgical/material industries.
Hydrodynamics of Bubble Column Reactors. This project will study the hydrodynamics of bubble columns with the aim of optimising these reactors for offshore gas-to-liquid plants. Along with experiments using the state-of-art techniques such as the particle image velocimetry, radioactive particle tracking, electrical capacitance tomography and optical probes, computational fluid dynamics simulations will be conducted to gain a deeper insight into bubble-induced turbulence and regime transitions in ....Hydrodynamics of Bubble Column Reactors. This project will study the hydrodynamics of bubble columns with the aim of optimising these reactors for offshore gas-to-liquid plants. Along with experiments using the state-of-art techniques such as the particle image velocimetry, radioactive particle tracking, electrical capacitance tomography and optical probes, computational fluid dynamics simulations will be conducted to gain a deeper insight into bubble-induced turbulence and regime transitions in these reactors. This information will then be used to devise scale-up strategies of these complex and industrially important equipment.Read moreRead less
Benign recovery of precious metals from deep pristine environments. This project aims to extract precious metals from natural deposits conventional mining methods cannot reach. Glycine-peroxide systems can dissolve precious metals without pollution. Understanding these systems’ behaviour in natural orebodies could lead to in-situ leaching methods that complement conventional mining, especially in low grade deposits. This project intends to use a modern scientific workflow based on exploratory, d ....Benign recovery of precious metals from deep pristine environments. This project aims to extract precious metals from natural deposits conventional mining methods cannot reach. Glycine-peroxide systems can dissolve precious metals without pollution. Understanding these systems’ behaviour in natural orebodies could lead to in-situ leaching methods that complement conventional mining, especially in low grade deposits. This project intends to use a modern scientific workflow based on exploratory, descriptive and explanatory phases to model the coupled multi-physics of precious metals transport, introduce a high performance computing strategy for in-situ leaching, develop an experimental protocol that explains the recovery mechanisms, and propose optimal leaching patterns that maximise productivity.Read moreRead less
New mesoporous materials for use in high temperature proton exchange fuel cell membranes. A novel high temperature proton exchange membrane based on heteropolyacid (HPA) functionalised mesoporous silica will be developed. This research into the fundamental materials science of novel proton exchange membranes is expected to impact significantly on the advancement and commercialisation of portable fuel cell devices.
A stochastic geometric framework for Bayesian sensor array processing. This project develops a mathematical framework, and a new generation of techniques, for sensor array processing to address real-world problems with uncertainty in array parameters and number of signals. The outcomes will enhance the capability of sensors in many application areas including, radar, sonar, astronomy and wireless communications.