Opening Up Access to L-Sugars through a Synergy of Experiment and Theory. This project aims to address a major bottleneck in the science of carbohydrates by developing the first broad-scope synthetic routes to L-sugars. L-sugars are critical components of many biologically and commercially significant molecules, but knowledge of their functional roles is impeded by the fact that most L-sugars are expensive or difficult to make. This project expects to develop expeditious routes to L-sugars via a ....Opening Up Access to L-Sugars through a Synergy of Experiment and Theory. This project aims to address a major bottleneck in the science of carbohydrates by developing the first broad-scope synthetic routes to L-sugars. L-sugars are critical components of many biologically and commercially significant molecules, but knowledge of their functional roles is impeded by the fact that most L-sugars are expensive or difficult to make. This project expects to develop expeditious routes to L-sugars via an innovative combination of synthetic and theoretical chemistry. Expected outcomes include a markedly increased capacity to access pure samples of L-sugar-based biomolecules, as needed for studying their biological functions. Significant benefits in the development of vaccines, diagnostics and biomaterials are anticipated.Read moreRead less
Preparing quantum chemistry for the second quantum revolution. This project aims to provide new computer models of quantum systems, which can be used to design new quantum technologies that exploit fundamental quantum physics, such as light harvesting. The benefits of such an approach are broad, as innovative technology firms can use its outputs in a virtual laboratory design process, saving time and costs. The work is significant, as it will bring a new physics-led approach to quantum chemistry ....Preparing quantum chemistry for the second quantum revolution. This project aims to provide new computer models of quantum systems, which can be used to design new quantum technologies that exploit fundamental quantum physics, such as light harvesting. The benefits of such an approach are broad, as innovative technology firms can use its outputs in a virtual laboratory design process, saving time and costs. The work is significant, as it will bring a new physics-led approach to quantum chemistry of excited states and open systems, which are likely to play a key role in future quantum technologies. It will also ensure Australia has well-trained computational chemists, who can take those skills to industry or academia; and will foster strong connections with Israel, a leader in the high-technology field.Read moreRead less
Solving the solvent problem in chemical modelling. This project aims to produce highly accurate, user-friendly chemical solvent models using interdisciplinary theoretical chemistry techniques. The benefits of these novel models are extremely broad since chemical modelling is more impactful than traditional laboratory based techniques in solving multi-faceted modern chemical problems. The proposed outcomes of the project are significant, as they will transform how applied research solves difficul ....Solving the solvent problem in chemical modelling. This project aims to produce highly accurate, user-friendly chemical solvent models using interdisciplinary theoretical chemistry techniques. The benefits of these novel models are extremely broad since chemical modelling is more impactful than traditional laboratory based techniques in solving multi-faceted modern chemical problems. The proposed outcomes of the project are significant, as they will transform how applied research solves difficult and expensive real world chemical problems by allowing researchers to reliably include solvents in their models. It will have economic benefits for the chemical, mining and materials sectors in Australia, which represent billion-dollar industries.Read moreRead less
Boosting Carbon Dioxide Reduction via Surface and Interface Engineering . This project will develop innovative catalysts for the reduction of CO2 into carbon fuels via cost effective computational design. The approach aims at engineering catalytic surface and interface to modulate the coordination environment around catalytic active copper atom. The expected outcomes will be high performance catalyst materials that can significantly boost the conversion of CO2 into valuable fuels. The new knowle ....Boosting Carbon Dioxide Reduction via Surface and Interface Engineering . This project will develop innovative catalysts for the reduction of CO2 into carbon fuels via cost effective computational design. The approach aims at engineering catalytic surface and interface to modulate the coordination environment around catalytic active copper atom. The expected outcomes will be high performance catalyst materials that can significantly boost the conversion of CO2 into valuable fuels. The new knowledge achieved in this project will dramatically advance the development of sustainable carbon cycle, providing solutions to the global energy supply and environmental issues. The smarter energy and environmental technologies will potentially result in the enhancements to the quality of the everyday lives of Australian.Read moreRead less