van der Waals epitaxy for advanced and flexible optoelectronics. This project aims to investigate the growth of compound semiconductors directly on two-dimensional material templates, via the so-called van der Waals epitaxy. Two-dimensional materials combined with compound semiconductors as optoelectronic materials can have many uses. This project expects to design flexible solar cells, which could be integrated with fabrics or building products, and lasers that need small drive currents. It wil ....van der Waals epitaxy for advanced and flexible optoelectronics. This project aims to investigate the growth of compound semiconductors directly on two-dimensional material templates, via the so-called van der Waals epitaxy. Two-dimensional materials combined with compound semiconductors as optoelectronic materials can have many uses. This project expects to design flexible solar cells, which could be integrated with fabrics or building products, and lasers that need small drive currents. It will use the Anderson localisation effect, a photon management concept, to control the interaction between photons and material and improve device efficiencies.Read moreRead less
Engineered ion channels for selective and switchable ion conduction. This project aims to develop an innovative bioinspired approach for fabricating angstrom-sized ion-channel membranes with specific ion selectivity, high ion conductivity and efficient gating function comparable to biological ion channels. Engineering of artificial channels with ion-channel-like shapes, ion selectivity filters and functional gates is expected to bring high-efficiency technologies to applications such as membrane ....Engineered ion channels for selective and switchable ion conduction. This project aims to develop an innovative bioinspired approach for fabricating angstrom-sized ion-channel membranes with specific ion selectivity, high ion conductivity and efficient gating function comparable to biological ion channels. Engineering of artificial channels with ion-channel-like shapes, ion selectivity filters and functional gates is expected to bring high-efficiency technologies to applications such as membrane separation and energy conversion. This project has potential to result in new knowledge of biomimetic design of artificial ion-channel membranes and directly benefit manufacturing industry for Australia.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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100004
Funder
Australian Research Council
Funding Amount
$470,000.00
Summary
Thin film processing cluster: precise synthesis and nano-patterning of functional coatings. This facility will allow Australian researchers to create advanced functional materials with unprecedented control over material configurations and near atomic scale precision in dimensions. This will enable significant advances in high speed photonics and electronics, health and environment monitoring, and micro-energy sources.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100127
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
Hall effect system for detailed electrical characterisation in semiconductors. Semiconductor characterisation is crucial for research and development in optimum growth and fabrication procedures. This Hall effect measurement system is an essential carrier characterisation technique for semiconductors with potential applications in microelectronics, optoelectronics and photovoltaics.