Electrochemistry of redox-active non-metal compounds. Unsaturated compounds of heavier non-metal elements can exist in multiple stable redox states. The interconversion is best assessed by electrochemical techniques, which can measure the energetics and the mechanism of the redox processes involved in both solution and solid state phases. Compounds to be studied will be prepared in the Canadian laboratories of the partner investigator. The electrochemical and spectroelectrochemical properties ....Electrochemistry of redox-active non-metal compounds. Unsaturated compounds of heavier non-metal elements can exist in multiple stable redox states. The interconversion is best assessed by electrochemical techniques, which can measure the energetics and the mechanism of the redox processes involved in both solution and solid state phases. Compounds to be studied will be prepared in the Canadian laboratories of the partner investigator. The electrochemical and spectroelectrochemical properties will initially be investigated in Australia during the visit of the partner investigator to Monash University with follow up studies in both countries. The mutual skills of synthesis and electrochemistry in the Canadian-Australian laboratories are essential to the project.Read moreRead less
Ionic Liquids and Solids - New Designs, Insights and Applications. Ionic Materials in the form of liquid salts and plastic crystals are of interest in a wide range of applications including environmentally benign synthesis of chemicals and high stability electrolytes for batteries, capacitors and other devices. These materials represent some of the most stable chemicals known, making them attractive for any application where complete stability and recycling are issues. Building on our recent wor ....Ionic Liquids and Solids - New Designs, Insights and Applications. Ionic Materials in the form of liquid salts and plastic crystals are of interest in a wide range of applications including environmentally benign synthesis of chemicals and high stability electrolytes for batteries, capacitors and other devices. These materials represent some of the most stable chemicals known, making them attractive for any application where complete stability and recycling are issues. Building on our recent work, this project will design, prepare and characterize novel materials of this type for a number of target applications. Collaborators in Europe and USA will be involved in the analysis and testing of the materials.Read moreRead less
Low viscosity, high ionic conductivity ionic liquids for lithium metal batteries. Current consumer electronic devices rely on lithium-ion batteries to provide a high energy density power source. There are growing safety concerns about the electrolytes in these devices after recent incidents involving fires in mobile phones. Recent advances in ionic liquids (ILs) have seen the development of new electrolytes for such devices, with enhanced physical properties that offer major safety advantages. H ....Low viscosity, high ionic conductivity ionic liquids for lithium metal batteries. Current consumer electronic devices rely on lithium-ion batteries to provide a high energy density power source. There are growing safety concerns about the electrolytes in these devices after recent incidents involving fires in mobile phones. Recent advances in ionic liquids (ILs) have seen the development of new electrolytes for such devices, with enhanced physical properties that offer major safety advantages. However, the viscosity of these materials currently limit their capabilities. New IL materials to be developed in this project will pave the way for the development of safer devices and new sustainable energy industries in Australia.Read moreRead less
Electrochemical Applications of Plastic Crystalline Electrolytes. A number of new and emerging electrochemical device applications such as lithium batteries, dye-sensitized solar cells, electrochemical capacitors, actuators and bio-sensors are limited by their need for a liquid electrolyte. Many of these devices are considered vital to energy efficiency and the lowering of greenhouse gas emissions. The recent discovery of ambient temperature plastic crystalline electrolyte materials by the Monas ....Electrochemical Applications of Plastic Crystalline Electrolytes. A number of new and emerging electrochemical device applications such as lithium batteries, dye-sensitized solar cells, electrochemical capacitors, actuators and bio-sensors are limited by their need for a liquid electrolyte. Many of these devices are considered vital to energy efficiency and the lowering of greenhouse gas emissions. The recent discovery of ambient temperature plastic crystalline electrolyte materials by the Monash Electrolytes group has raised the possibility of solving this problem. In this project new plastic crystalline electrolyte materials will be developed to suit these applications and their electrochemical properties investigated. Laboratory prototype devices will be prepared and tested and via collaborations with appropriate device developers, their performance evaluted.Read moreRead less
Polyoxometalate Clusters: Catalytic Chemistry in Solution and Condensed States. Polyoxometalate cluster anions are soluble metal-oxygen clusters that are cheap, robust and non-toxic.
Conditions for systematic tuning of redox potentials over the range +2 to -3 V have become accessible via certain photo-active polyoxometalates. The same system can provide powerful oxidants (that rival chlorine) and powerful reductants (that rival potassium).
The program will take advantage of this unique ....Polyoxometalate Clusters: Catalytic Chemistry in Solution and Condensed States. Polyoxometalate cluster anions are soluble metal-oxygen clusters that are cheap, robust and non-toxic.
Conditions for systematic tuning of redox potentials over the range +2 to -3 V have become accessible via certain photo-active polyoxometalates. The same system can provide powerful oxidants (that rival chlorine) and powerful reductants (that rival potassium).
The program will take advantage of this unique range of properties to explore:-
(i) coupling of photo- and electro-chemical processes into effective catalytic cycles;
(ii) photo- and electro-chemical processes in ionic liquid solvents;
(iii) synthesis and redox reactivity of nanoparticles stabilised by polyoxometalates.
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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
Tuning the electrolytes for high efficiency solar splitting of water. This project will develop a new technology that uses ionic liquids and sunlight to split water into hydrogen and oxygen to be used as a clean fuel. Australia has abundant sunlight, is very close to the growing energy markets of the Asia-Pacific region, and is ideally placed to benefit from this new technology.
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