Bioinspired Ion Transporters for Efficient Energy Conversion and Storage. This project aims to fabricate bioinspired light-driven ion transporters with biological-level active ion transport efficiency for efficient energy conversion and storage. Engineering of artificial membranes with ion-pump-like pore structures, specific ion binding sites and photo-excited molecular gates by an innovative bioinspired approach is expected to generate new knowledge in the field of biomimetic design of artifici ....Bioinspired Ion Transporters for Efficient Energy Conversion and Storage. This project aims to fabricate bioinspired light-driven ion transporters with biological-level active ion transport efficiency for efficient energy conversion and storage. Engineering of artificial membranes with ion-pump-like pore structures, specific ion binding sites and photo-excited molecular gates by an innovative bioinspired approach is expected to generate new knowledge in the field of biomimetic design of artificial ion-transporter membranes and bring new technologies to applications such as in solar energy harvesting, osmotic power generation, ionic batteries, and ionic circuits. The proposed research should provide significant benefits such as new energy conversion and storage technologies for Australian manufacturing industry.Read moreRead less
Porous transparent conducting oxides for efficient solar fuel production. This project aims to develop highly porous, transparent and electrically conducting networks of oxide nanoparticles for artificial photosynthesis applications. The majority of hydrogen is currently produced via natural gas reforming, a process that generates a significant carbon footprint due to the use of fossil fuels. This project will develop novel materials and fabrication methods to improve the efficiency of hydrogen ....Porous transparent conducting oxides for efficient solar fuel production. This project aims to develop highly porous, transparent and electrically conducting networks of oxide nanoparticles for artificial photosynthesis applications. The majority of hydrogen is currently produced via natural gas reforming, a process that generates a significant carbon footprint due to the use of fossil fuels. This project will develop novel materials and fabrication methods to improve the efficiency of hydrogen production using clean and renewable solar energy. This project will contribute to development of technologies for the chemical storage of renewable energy, and reduction of carbon dioxide emissions. This will have applications in the areas of optoelectronic devices, medical biosensors, and photocatalysis, offering downstream benefits for the society, the economy and the environment.Read moreRead less