Electrochemically, photochemically and magnetically tuneable organic semi-conducting electrodes for probing biologically important redox chemistry and catalysis. Newly developed tuneable, semi-conductor electrode materials will facilitate substantial advances in electrochemistry. The almost unprecedented levels of flexibility with respect to metal and organic constituents will facilitate insights into biologically important electron transfer and coupled catalytic processes and promote commercia ....Electrochemically, photochemically and magnetically tuneable organic semi-conducting electrodes for probing biologically important redox chemistry and catalysis. Newly developed tuneable, semi-conductor electrode materials will facilitate substantial advances in electrochemistry. The almost unprecedented levels of flexibility with respect to metal and organic constituents will facilitate insights into biologically important electron transfer and coupled catalytic processes and promote commercial opportunities for sensor development. Electrochemistry represents an enabling discipline in science. The project offers the opportunity for high quality multi-disciplinary doctoral training, integration of skills of scientists from different backgrounds and opportunities to work in world-class national and international infrastructure in the areas of chemistry, biological chemistry and materials science.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.
Integration of Electrochemistry and Green Chemistry: A Roadmap for Scientific Innovation. Electrochemistry represents an enabling science in physical, chemical and life sciences. It plays a key role in fundamental studies and in Australia's industrial capacity to exploit emerging technologies. Research conducted synergistically within the ARC Centre for Green Chemistry would enable the Monash Electrochemistry Group to develop and exploit new concepts. In the national interest, the Fellowship ....Integration of Electrochemistry and Green Chemistry: A Roadmap for Scientific Innovation. Electrochemistry represents an enabling science in physical, chemical and life sciences. It plays a key role in fundamental studies and in Australia's industrial capacity to exploit emerging technologies. Research conducted synergistically within the ARC Centre for Green Chemistry would enable the Monash Electrochemistry Group to develop and exploit new concepts. In the national interest, the Fellowship would: facilitate global participation in cutting-edge science derived from electrochemical and green chemical concepts; provide commercial opportunities for new and mature chemical industries; expand postgraduate training; and promote technology exchange with Australian and international leading-edge research organisations.Read moreRead less
Large amplitude Fourier transformed voltammetry: paths towards more efficient data evaluation strategies, enhanced insights and innovation in dynamic electrochemistry. Electrochemistry represents an enabling discipline in many branches of science. The aim of this research is to integrate the collective skills of an international consortium of experts in electrochemistry, electrical engineering, computing and mathematics in order to implement a blueprint proposed for innovation in electrochemic ....Large amplitude Fourier transformed voltammetry: paths towards more efficient data evaluation strategies, enhanced insights and innovation in dynamic electrochemistry. Electrochemistry represents an enabling discipline in many branches of science. The aim of this research is to integrate the collective skills of an international consortium of experts in electrochemistry, electrical engineering, computing and mathematics in order to implement a blueprint proposed for innovation in electrochemical science. In the national interest, the project will facilitate global participation in cutting-edge science derived from electrochemical concepts, provide commercial opportunities in the area of scientific instrumentation and promote technology exchange with Australian and international leading-edge research organizations.Read moreRead less
A blueprint for an intelligent instrumental, theoretical and experimental unification of a myriad of voltammetric and related electrochemical techniques. Electrochemistry is a prominent discipline in many areas of fundamental and applied science (for example, electron transfer reactions, corrosion, sensors, photovoltaics). The aim of the research proposal is to utilise skills available at Monash University and those of a national and international consortium of experts in electrochemistry, elec ....A blueprint for an intelligent instrumental, theoretical and experimental unification of a myriad of voltammetric and related electrochemical techniques. Electrochemistry is a prominent discipline in many areas of fundamental and applied science (for example, electron transfer reactions, corrosion, sensors, photovoltaics). The aim of the research proposal is to utilise skills available at Monash University and those of a national and international consortium of experts in electrochemistry, electrical engineering, computing and mathematics to introduce a new integrated instrumental, theoretical and experimental concept that will provide a blueprint for innovation in electrochemical science. An expected outcome is that important advances relevant to Australian Industry will be achieved in the area of scientific instrumentation and in modern applications of electrochemistry.Read moreRead less
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
Novel Scanning Electrochemical Microscopy applications in molecular, supramolecular electrochemistry and biological systems. Improved understanding of chemical reactivity in natural and artificial molecular systems and acquisition of a wider perspective of electron transfer processes are two important challenges in chemistry and biology. Through this well defined research project, the CI, jointly with the host facility, has the skills to achieve valuable new insights. This project will expand Au ....Novel Scanning Electrochemical Microscopy applications in molecular, supramolecular electrochemistry and biological systems. Improved understanding of chemical reactivity in natural and artificial molecular systems and acquisition of a wider perspective of electron transfer processes are two important challenges in chemistry and biology. Through this well defined research project, the CI, jointly with the host facility, has the skills to achieve valuable new insights. This project will expand Australia's knowledge base and research capability and open new scenarios for frontier technologies and advanced materials. This project will introduce the SECM methods into Australia. The foreseen benefits include technology exchange and contribution to fundamental and applied science.Read moreRead less
Blocking of the interfaces of polymeric ion sensors - implications for novel sensor applications. Control of the transmembrane fluxes of polymeric ion sensors represents a paradigm shift that has revolutionised the use of these analytically important devices. This project will develop and characterise innovative methods for controlling these fluxes by using blocked interfaces, and this has important ramifications for the development of robust and reliable sensors, as well as novel biosensors.
Nanoscale liquid interfaces: properties and molecular sensitivity. Challenges facing society in health and environment need new molecular measurements that are accurate, sensitive and fast. By use of nanoscale oil-water junctions, the project will develop new chemical and biological sensors that hold great promise for solving molecular measurement problems, including the ability to detect single molecules.