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
The role of water uptake in novel all solid-state polymeric ion sensors. This research will enable the development of robust all solid-state polymeric ion sensors based on unplasticized copolymers. Significantly, the physical and chemical robustness of these copolymer ion sensors will allow their widespread use in new and exciting analytical applications, e.g., in-situ analysis of environmental samples in submersible instruments, clinical analysis of whole blood, in-vivo use of miniaturized ele ....The role of water uptake in novel all solid-state polymeric ion sensors. This research will enable the development of robust all solid-state polymeric ion sensors based on unplasticized copolymers. Significantly, the physical and chemical robustness of these copolymer ion sensors will allow their widespread use in new and exciting analytical applications, e.g., in-situ analysis of environmental samples in submersible instruments, clinical analysis of whole blood, in-vivo use of miniaturized electrodes in biological media, especially single cells and minute samples in biology and forensic science, etc. Extensive use of neutron characterization techniques aligns strongly this project with the new OPAL reactor to be commissioned in 2007.Read moreRead less
Probing the internal contacts of all solid-state polymeric ion sensors. The results of this research will enable the development of robust and reliable all solid-state polymeric ion sensors. These sensors will enable solutions to significant environmental problems such as soil salinity and acidity, and may pave the way for new and exciting analytical applications, e.g., miniaturized implantable sensors for in-vivo use, microfluidics and Forensic Science, single blood droplet clinical analyzers, ....Probing the internal contacts of all solid-state polymeric ion sensors. The results of this research will enable the development of robust and reliable all solid-state polymeric ion sensors. These sensors will enable solutions to significant environmental problems such as soil salinity and acidity, and may pave the way for new and exciting analytical applications, e.g., miniaturized implantable sensors for in-vivo use, microfluidics and Forensic Science, single blood droplet clinical analyzers, rugged solid contact ion sensors for use in submersible oceanographic analyzers, etc. The research will develop a unique in-situ neutron reflectometry technique for the study of electrochemical interfaces, providing scientific opportunities for the new Australian Replacement Research Reactor.Read moreRead less
Probing the interfaces of electrochemical sensors. The nanostructured surfaces of electrochemical sensors for iron, mercury and cadmium will be characterised by using a range of state-of-the-art surface analysis techniques. Whilst electrochemical sensors are extremely valuable in monitoring of trace metals in the aquatic environment, a knowledge of the surface chemical physics of the systems is vital in order to widen their use in analytical/environmental chemistry. This project will derive a u ....Probing the interfaces of electrochemical sensors. The nanostructured surfaces of electrochemical sensors for iron, mercury and cadmium will be characterised by using a range of state-of-the-art surface analysis techniques. Whilst electrochemical sensors are extremely valuable in monitoring of trace metals in the aquatic environment, a knowledge of the surface chemical physics of the systems is vital in order to widen their use in analytical/environmental chemistry. This project will derive a universal model for the surface chemistry and physics of electrochemical sensors, enabling environmental scientists to develop unique sensor methods for studying the speciation of environmentally important trace metals such as those mentioned above.Read moreRead less
Better Batteries via Controlling the Properties of Electrolytic Manganese Dioxide. Physical properties of electrolytic manganese dioxide (EMD) such as crystal structure, morphology and electrochemical characteristics determine its usefulness in alkaline batteries. However, the relationship between these parameters is not well understood. This APAI project will attempt to address these shortcomings in the current understanding of the production process by focussing on the relationships between fu ....Better Batteries via Controlling the Properties of Electrolytic Manganese Dioxide. Physical properties of electrolytic manganese dioxide (EMD) such as crystal structure, morphology and electrochemical characteristics determine its usefulness in alkaline batteries. However, the relationship between these parameters is not well understood. This APAI project will attempt to address these shortcomings in the current understanding of the production process by focussing on the relationships between fundamental physical, chemical and electrochemical properties of EMD. The results will be of benefit in optimising the process and ensuring that EMD with superior performance can be consistently produced.Read moreRead less
Light Activated Electrochemistry: Microelectrode Arrays with just one wire. Electrochemistry requires each electrode to be connected to the external circuit by a wire. With many electrodes this means many wires. Wires limit electrode density in arrays and dictate that the electrode architecture must be predetermined. This project aims to remove the need for a wire for each electrode by using light to sequentially connect each electrode to a single wire. This will be achieved using modified silic ....Light Activated Electrochemistry: Microelectrode Arrays with just one wire. Electrochemistry requires each electrode to be connected to the external circuit by a wire. With many electrodes this means many wires. Wires limit electrode density in arrays and dictate that the electrode architecture must be predetermined. This project aims to remove the need for a wire for each electrode by using light to sequentially connect each electrode to a single wire. This will be achieved using modified silicon electrodes where irradiating with light causes an increase in conductivity at the illumination spot. The project will explore the variables that influence the spatial resolution and apply the ideas to making soft connects for nanoelectronics and making high density electrode arrays for electroanalysis.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101456
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Electrochemical behaviour of toxic gases and explosives in room temperature ionic liquids. This project will examine the behaviour of toxic gases and volatile explosive materials in ionic liquids. The information generated from this work will provide fundamental knowledge that will allow for the design of improved sensors for toxic gases, nerve agents and explosives, for applications in the mining and security sectors.
Discovery Early Career Researcher Award - Grant ID: DE160100732
Funder
Australian Research Council
Funding Amount
$359,544.00
Summary
Electrostatic Catalysis: guiding reactive interfaces using electric fields. This project seeks to gain quantitative understanding of the role of electrostatics over chemical processes. Chemical transformations of organic compounds at interfaces underpin some of the most important processes, from the production of fine chemicals for pharmaceuticals to assisting bio-degradation of pollutants in clean technologies. Recent computational studies suggest that by applying oriented electric fields at in ....Electrostatic Catalysis: guiding reactive interfaces using electric fields. This project seeks to gain quantitative understanding of the role of electrostatics over chemical processes. Chemical transformations of organic compounds at interfaces underpin some of the most important processes, from the production of fine chemicals for pharmaceuticals to assisting bio-degradation of pollutants in clean technologies. Recent computational studies suggest that by applying oriented electric fields at interfaces, the rate and the selectivity of chemical processes can be altered at will. The project intends to test these theoretical findings. The knowledge generated by this research may translate into new technologies for the fine-chemical and biotechnology industries.Read moreRead less
Solid-State Battery Interface Design (SS-BID). This research project aims to use the world’s best performing solid-state ion conductors to develop next generation solid-state batteries. Boron-rich electrolytes will be paired with lithium metal anodes to construct batteries that are more energy dense, safer, have wider operational temperature windows, and aim to be lower cost than existing Li-ion batteries. The current roadblock for these batteries lies in the poorly performing interfaces between ....Solid-State Battery Interface Design (SS-BID). This research project aims to use the world’s best performing solid-state ion conductors to develop next generation solid-state batteries. Boron-rich electrolytes will be paired with lithium metal anodes to construct batteries that are more energy dense, safer, have wider operational temperature windows, and aim to be lower cost than existing Li-ion batteries. The current roadblock for these batteries lies in the poorly performing interfaces between anode, electrolyte and cathode. This research aims to develop new strategies to overcome these barriers and perform world-class measurement techniques to understand and optimise solid-state batteries to provide a commercially viable energy storage solution.Read moreRead less
Nanoscale Dynamics and Structure of SAILs at Electrodes. This project will produce new, high performance, surface active ionic liquids. Surface active ionic liquids are pure salts in which one of the ions is based on a surfactant molecule. Surface active ionic liquids are much more effective than conventional electrolytes for some applications, but only at elevated temperature; at low temperature, ion dynamics are too slow. We will use cutting edge techniques to probe ion dynamics in surface act ....Nanoscale Dynamics and Structure of SAILs at Electrodes. This project will produce new, high performance, surface active ionic liquids. Surface active ionic liquids are pure salts in which one of the ions is based on a surfactant molecule. Surface active ionic liquids are much more effective than conventional electrolytes for some applications, but only at elevated temperature; at low temperature, ion dynamics are too slow. We will use cutting edge techniques to probe ion dynamics in surface active ionic liquids in the bulk and at electrode surfaces, and use this to elucidate rules for the rational design of new surface active ionic liquids with fast dynamics at low temperature, towards their use at room temperature in diverse areas; this project will target capacitors and gas sensors. Read moreRead less