Computer-Aided Design of High-Performance Photocatalysts for Solar Hydrogen Production Based on Red Titanium Dioxide. Large-scale generation of energy by solar conversion is critical for future sustainability. This project aims to develop high performance materials to efficiently convert solar energy to hydrogen - a clean fuel. Starting from the newly developed material red titanium dioxide, novel strategies for improved photocatalytic materials will be proposed and evaluated by advanced computa ....Computer-Aided Design of High-Performance Photocatalysts for Solar Hydrogen Production Based on Red Titanium Dioxide. Large-scale generation of energy by solar conversion is critical for future sustainability. This project aims to develop high performance materials to efficiently convert solar energy to hydrogen - a clean fuel. Starting from the newly developed material red titanium dioxide, novel strategies for improved photocatalytic materials will be proposed and evaluated by advanced computational approaches. Key issues for solar-to-hydrogen conversion will be clarified. The materials, knowledge and strategies achieved by this project will dramatically enhance current solar technology and in particular will advance the development of low-cost hydrogen production from water. Read moreRead less
Nanostructuring and nanocharacterisation of organic semiconductor devices. This research project will utilise new approaches to pattern organic solar cells on the nanoscale to realise improved efficiencies and improved understanding of device operation. It will also develop soft x-ray techniques to probe the nanostructure of organic semiconductor films with increased chemical and interfacial specificity.
Towards ab initio molecular dynamics simulations of proton and electron transfer processes. Electrochemical technologies seek design capabilities to enable the discovery of novel electrolytes with valuable properties. This project will develop new advanced computational methods to understand electron and proton transfer in electrolytes and thereby allow us to enhance performance of electrochemical devices and control metal deposition.
Luminophores and photochromes: towards molecular componentry. This project aims to enhance current knowledge of luminogenic and photochromic molecules, including self-assembled structures, and materials composed thereof, by constructing a computationally guided compound library. Translation of primary outcomes towards utility in emerging technologies including passive light harvesting from transparent surfaces, bio-sensors and photo-responsive devices will be pursued in collaboration with both a ....Luminophores and photochromes: towards molecular componentry. This project aims to enhance current knowledge of luminogenic and photochromic molecules, including self-assembled structures, and materials composed thereof, by constructing a computationally guided compound library. Translation of primary outcomes towards utility in emerging technologies including passive light harvesting from transparent surfaces, bio-sensors and photo-responsive devices will be pursued in collaboration with both academia and industry. The expected outcomes from this project include the creation of opportunities to explore the manufacture and commercialisation of high-value products with Australian industry. This will provide significant benefits, such as reduction in the carbon footprint of homes, businesses and other applicable structures due to passive power generation, while creating jobs and up-skilling the workforce.Read moreRead less
Supramolecular assembly of chromophores:the effects of nucleation kinetics on their molecular packing, fibre structure and light harvesting efficiency. This project aims to reveal the effects of nucleation kinetics of chromophores on their molecular packing, fibre structure and energy transfer efficiency, which are significant to the design of low cost and lightweight materials for high efficiency solar energy harvesting. The knowledge to be acquired addresses the bottleneck governing the effici ....Supramolecular assembly of chromophores:the effects of nucleation kinetics on their molecular packing, fibre structure and light harvesting efficiency. This project aims to reveal the effects of nucleation kinetics of chromophores on their molecular packing, fibre structure and energy transfer efficiency, which are significant to the design of low cost and lightweight materials for high efficiency solar energy harvesting. The knowledge to be acquired addresses the bottleneck governing the efficiency of a class of novel materials that mimic the natural light harvesting systems. It will bring about health, economic and environmental benefits to Australia. This project will foster multidisciplinary collaborations between world class research centres.Read moreRead less