Next-generation reaction-environments tunable catalysts for CO2 reduction. This project aims to design and develop next-generation reaction-environments tunable catalysts for active, selective and stable CO2 conversion to higher-value fuels/chemicals. Fundamentally new materials design in combination with modern computational methods and advanced in/ex-situ instrumental techniques will be advanced to develop a series of functional catalysts for customisable CO2 conversion. Expected outcomes incl ....Next-generation reaction-environments tunable catalysts for CO2 reduction. This project aims to design and develop next-generation reaction-environments tunable catalysts for active, selective and stable CO2 conversion to higher-value fuels/chemicals. Fundamentally new materials design in combination with modern computational methods and advanced in/ex-situ instrumental techniques will be advanced to develop a series of functional catalysts for customisable CO2 conversion. Expected outcomes include new understandings of heterogenous catalysis tailorable with reaction environments and innovations in energy conversion and CO2 utilisation applications. These will provide educational and technological benefits for Australia, spanning material sciences, advanced manufacturing, carbon utilisation and renewable energy.Read moreRead less
Nanoengineered hybrid coatings that control inflammation to artificial bone. This project aims to develop novel biocompatible surfaces using nanotechnology approaches to understand how cells attach to and grow on artificial bone materials. This research is significant because it combines novel nanofabrication and surface modification strategies for unprecedented control and manipulation of inflammatory cell behaviour relevant to orthopaedic implants. The project will overcome current limitations ....Nanoengineered hybrid coatings that control inflammation to artificial bone. This project aims to develop novel biocompatible surfaces using nanotechnology approaches to understand how cells attach to and grow on artificial bone materials. This research is significant because it combines novel nanofabrication and surface modification strategies for unprecedented control and manipulation of inflammatory cell behaviour relevant to orthopaedic implants. The project will overcome current limitations of uncontrollable inflammatory reactions to surfaces. The multifunctional surfaces are expected to give the biomaterials field new tools to control and maintain bone cell functionality, in vitro. Potential long-term benefits include applications as coatings in tissue engineering, regenerative medicine, and medical implants.Read moreRead less