Photoelectrode design for solar driven methane to methanol conversion. This project aims to achieve efficient photoelectrocatalytic partial oxidation of greenhouse gas methane for methanol production with high selectivity. The program will design new semiconductor materials through rational defect engineering and co-catalyst selection to revolutionise methane conversion. The expected outcomes include sustainable processes to convert methane into valuable liquid chemicals like methanol, and compr ....Photoelectrode design for solar driven methane to methanol conversion. This project aims to achieve efficient photoelectrocatalytic partial oxidation of greenhouse gas methane for methanol production with high selectivity. The program will design new semiconductor materials through rational defect engineering and co-catalyst selection to revolutionise methane conversion. The expected outcomes include sustainable processes to convert methane into valuable liquid chemicals like methanol, and comprehensive understanding on functional material design for solar driven catalytic reactions. The significant benefits will include revolutionary methane mitigation technologies and sustainable processes for value-added chemical production, alleviating key environmental and energy challenges facing Australia and the world.Read moreRead less
Bio-inspired Nanoparticles for Mechano-Regulation of Stem Cell Fate. Mechanical stimulation plays a critical role in regulating stem cell fate. Nanostructure-mediated mechanical cues can precisely stimulate stem cells, but predicting their impact on stem cell differentiation is challenging. This project aims to engineer nanostructures to regulate stem cell fate and gain a fundamental understanding of the mechanical properties that affect cell function. The expected outcomes and benefits of this ....Bio-inspired Nanoparticles for Mechano-Regulation of Stem Cell Fate. Mechanical stimulation plays a critical role in regulating stem cell fate. Nanostructure-mediated mechanical cues can precisely stimulate stem cells, but predicting their impact on stem cell differentiation is challenging. This project aims to engineer nanostructures to regulate stem cell fate and gain a fundamental understanding of the mechanical properties that affect cell function. The expected outcomes and benefits of this project include a new fundamental understanding of the effect of mechanical properties on cell function, novel insights into the regulation of stem cell fate, and the development of a new class of roughness-tunable materials suitable for use in tissue engineering and pharmaceutical applications. Read moreRead less