Switching, sensing and multifunctionality in spin crossover materials. This project aims to increase the temperature range where molecular spin states can be switched optically or electronically, and to develop new multifunctional materials combining switchable hosts with functional guests. By combining novel theories, synthesis and experiments, this project expects to generate step-change advances in the understanding of spin-switching materials and discover materials with novel properties wort ....Switching, sensing and multifunctionality in spin crossover materials. This project aims to increase the temperature range where molecular spin states can be switched optically or electronically, and to develop new multifunctional materials combining switchable hosts with functional guests. By combining novel theories, synthesis and experiments, this project expects to generate step-change advances in the understanding of spin-switching materials and discover materials with novel properties worthy of commercial development. Significant anticipated outcomes and benefits include the identification and development of several new classes of materials function, each of major fundamental interest, and the generation of new advanced materials with applications in electronics, sensing and gas separations.Read moreRead less
High activity catalysts for CO2 recycling to valuable chemical products. This proposal targets the development of novel porous solid catalysts, containing highly dispersed metal clusters that provide exceptional activity for the conversion (recycling) of carbon dioxide to fuels and other higher value chemical products. These novel materials will improve the productivity and/or reduce the energy required to facilitate the CO2 conversion, thereby reducing costs for industry, whilst also providing ....High activity catalysts for CO2 recycling to valuable chemical products. This proposal targets the development of novel porous solid catalysts, containing highly dispersed metal clusters that provide exceptional activity for the conversion (recycling) of carbon dioxide to fuels and other higher value chemical products. These novel materials will improve the productivity and/or reduce the energy required to facilitate the CO2 conversion, thereby reducing costs for industry, whilst also providing environmental benefit by carbon dioxide utilisation.Read moreRead less
“Janus” Transition Metal Dichalcogenides: Quest for Novel Properties . Novel two-dimensional nanomaterials – so called “Janus” transition metal dichalcogenides (TMDs) - are featured by breaking out-of-plane structural symmetry that enables prolongated exciton lifetime, strong spin-orbit coupling, large vertical piezoelectric polarization, and exceptional electromechanical properties. We plan to develop reliable and efficient synthetic routes for various "Janus" TMDs and their heterostructures, ....“Janus” Transition Metal Dichalcogenides: Quest for Novel Properties . Novel two-dimensional nanomaterials – so called “Janus” transition metal dichalcogenides (TMDs) - are featured by breaking out-of-plane structural symmetry that enables prolongated exciton lifetime, strong spin-orbit coupling, large vertical piezoelectric polarization, and exceptional electromechanical properties. We plan to develop reliable and efficient synthetic routes for various "Janus" TMDs and their heterostructures, to investigate their physical properties, and find the ways of property tailoring. Deep understanding of structure-property relationships uncovered for these materials will pave the way for transferring discovered new features into cutting-edge technologies in electromechanical, optoelectronic, and catalytic fields.Read moreRead less
Zwitterion-based electrolytes for advanced energy technologies. This research aims to develop a new class of electrolyte that is safer, non-flammable and designed to enable excellent performance of high energy batteries made with either sodium or lithium. Through the synthesis of new electrolyte structures that are designed to improve stability and electrochemical properties, and using a range of analysis techniques to understand the material properties, the project aims to solve some of the saf ....Zwitterion-based electrolytes for advanced energy technologies. This research aims to develop a new class of electrolyte that is safer, non-flammable and designed to enable excellent performance of high energy batteries made with either sodium or lithium. Through the synthesis of new electrolyte structures that are designed to improve stability and electrochemical properties, and using a range of analysis techniques to understand the material properties, the project aims to solve some of the safety and performance problems that plague existing electrolytes. Expected benefits include new functional energy materials for safer, more reliable energy storage technologies, plus research training, collaborations and materials development capabilities to help position Australia as a global leader in this field.Read moreRead less