Advanced Polymer Electrolytes for Device Applications. The future of an energy sustainable society relies upon the development of a range of technologies that will involve devices such as lithium batteries, supercapacitors, sensors and fuel cells. One of the key challenges is the discovery and development of high performance materials which overcome performance limiting issues such as conductivity, durability and stability in current devices. Our recent discovery of novel successful approaches ....Advanced Polymer Electrolytes for Device Applications. The future of an energy sustainable society relies upon the development of a range of technologies that will involve devices such as lithium batteries, supercapacitors, sensors and fuel cells. One of the key challenges is the discovery and development of high performance materials which overcome performance limiting issues such as conductivity, durability and stability in current devices. Our recent discovery of novel successful approaches to the design of improved electrolyte materials will be systematically exploited to develop materials that will provide the significant advance in device performance that is required.Read moreRead less
Characterization and design of new soft electrolyte materials. The use of fossil fuels for energy generation contributes heavily to global warming. The development of new types of energy sources (e.g. fuel cells) and energy storage devices (e.g. batteries) is of crucial importance to ease this pressure on the environment. The search for new, high energy-density electrolyte materials for these applications is intense. Recently, plastic crystal materials have been identified as potential electroly ....Characterization and design of new soft electrolyte materials. The use of fossil fuels for energy generation contributes heavily to global warming. The development of new types of energy sources (e.g. fuel cells) and energy storage devices (e.g. batteries) is of crucial importance to ease this pressure on the environment. The search for new, high energy-density electrolyte materials for these applications is intense. Recently, plastic crystal materials have been identified as potential electrolytes in a variety of electrochemical devices. These materials show high conductivity at ambient temperatures in their plastic (or soft) phase. This project aims to further investigate and develop these novel materials.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989487
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
The National Hydrogen Materials Reference Facility. Hydrogen energy technology is a vital element in the global response to climate change owing to increasing atmospheric carbon dioxide levels from burning fossil fuels. Hydrogen is a universal energy carrier that facilitates the transformation of energy from renewable and other sources for applications in industry, transport and homes. The National Hydrogen Materials Reference Facility is a multidisciplinary, state-of-the-art experimental facili ....The National Hydrogen Materials Reference Facility. Hydrogen energy technology is a vital element in the global response to climate change owing to increasing atmospheric carbon dioxide levels from burning fossil fuels. Hydrogen is a universal energy carrier that facilitates the transformation of energy from renewable and other sources for applications in industry, transport and homes. The National Hydrogen Materials Reference Facility is a multidisciplinary, state-of-the-art experimental facility for materials science supporting excellent research into advanced materials for hydrogen generation from fossil fuels and by solar means, hydrogen storage for automotive and stationary applications, hydrogen distribution and hydrogen end use, particularly in fuel cells that generate electricity.Read moreRead less
Interphase Engineering of Reactive Metal Surfaces Using Ionic Liquids. Corrosion is a multi-billion dollar problem for all developed countries which limits the use of a number of advanced, light weight alloys in applications ranging from aircraft components to artificial hip-joints. The outcomes of this project will be surface treatments which will enable a range of these applications including magnesium alloys in a wider range of engineering uses, magnesium for advanced metal batteries and coat ....Interphase Engineering of Reactive Metal Surfaces Using Ionic Liquids. Corrosion is a multi-billion dollar problem for all developed countries which limits the use of a number of advanced, light weight alloys in applications ranging from aircraft components to artificial hip-joints. The outcomes of this project will be surface treatments which will enable a range of these applications including magnesium alloys in a wider range of engineering uses, magnesium for advanced metal batteries and coatings for medical implant applications. Many of these applications will make a significant contribution to reducing our greenhouse gas emissions.Read moreRead less
Development of nonvolatile fast proton-transport materials. There are many problems with existing proton-transport materials for emerging fuel cell applications such as electric vehicles. A high proton conductivity and high thermal stability are some of the requirements for fuel cell electrolytes. The aims of this project are to develop nonvolatile proton-transport matrices based on zwitterionic liquids with various acids, develop polymer gel materials based on these, and characterize these ne ....Development of nonvolatile fast proton-transport materials. There are many problems with existing proton-transport materials for emerging fuel cell applications such as electric vehicles. A high proton conductivity and high thermal stability are some of the requirements for fuel cell electrolytes. The aims of this project are to develop nonvolatile proton-transport matrices based on zwitterionic liquids with various acids, develop polymer gel materials based on these, and characterize these new proton-transport materials by analyzing ionic conductivity, viscosity, thermal behaviors, and their interrelationships.Read moreRead less
Understanding, Control, and Optimisation of Free Volume Mediated Transport in Technologically Important Materials. The understanding gained by this work will enable Australian scientists to outpace their competitors in rational materials design for transport of atoms and molecules in materials while reducing the costly trial and error stage of research. Specific examples studied and new materials investigated have important technological significance from use in flat panel TV screens, to solid ....Understanding, Control, and Optimisation of Free Volume Mediated Transport in Technologically Important Materials. The understanding gained by this work will enable Australian scientists to outpace their competitors in rational materials design for transport of atoms and molecules in materials while reducing the costly trial and error stage of research. Specific examples studied and new materials investigated have important technological significance from use in flat panel TV screens, to solid state electrolytes for application in a wide range of electrochemical devices. The understanding gained by this work can be applied to a wide range of important materials e.g. separation membranes, nanofilters and catalysts which help address a number of National Research Priorities.Read moreRead less