Quantum coherence and many-body interactions in inorganic and organic nanoscale electronic devices. The multi-trillion dollar semiconductor industry drives the explosive growth in information technology that we have witnessed over the past 25 years. Although Australia is not presently a major player in the industry, this proposal will enable Australia to play a role in its future development of nanoscale electronics, both in conventional (inorganic) semiconductor devices, and in new (organic) de ....Quantum coherence and many-body interactions in inorganic and organic nanoscale electronic devices. The multi-trillion dollar semiconductor industry drives the explosive growth in information technology that we have witnessed over the past 25 years. Although Australia is not presently a major player in the industry, this proposal will enable Australia to play a role in its future development of nanoscale electronics, both in conventional (inorganic) semiconductor devices, and in new (organic) device technologies based on carbon nanotubes. This research program will allow Australian researchers and students to work both with leading international universities (Cambridge (UK) and Copenhagen (Denmark), and a leading Japanese industrial research facility - Nippon Telegraph and Telecommunications.Read moreRead less
Tailored porphyrins for nanoscience applications. Porphyrins are the pigments of life, the central components of haemoglobin in blood and chlorophyll in living plants. In order to expand their use into important areas of nanoscience, this project will establish a new porphyrin paradigm. It will result in the synthesis of novel porphyrins with inbuilt structural features that enhance their propensity to self-assemble into monolayers on surfaces, and into nanorods. This will lead to advanced mate ....Tailored porphyrins for nanoscience applications. Porphyrins are the pigments of life, the central components of haemoglobin in blood and chlorophyll in living plants. In order to expand their use into important areas of nanoscience, this project will establish a new porphyrin paradigm. It will result in the synthesis of novel porphyrins with inbuilt structural features that enhance their propensity to self-assemble into monolayers on surfaces, and into nanorods. This will lead to advanced materials for molecular sensing, photonics, molecular memory devices, catalysis, and organic photovoltaics. A new means of improving the efficiency of solar cells will also be explored. Well-trained graduates and strong international scientific cooperation will also result from the project.Read moreRead less