Vertically-aligned Single-walled Carbon Nanotube and Quantum Dot Junctions: A New Concept for Optically-tunable Three-dimensional Information Storage and Processing. The proposed study will have a direct impact to computer science and engineering and may provide new routes for application-oriented optoelectronic devices with outstanding performance. As industry gets closer to the realization of nanoscale applications, there will be a need of people who are educated in nanoscience and nanotechnol ....Vertically-aligned Single-walled Carbon Nanotube and Quantum Dot Junctions: A New Concept for Optically-tunable Three-dimensional Information Storage and Processing. The proposed study will have a direct impact to computer science and engineering and may provide new routes for application-oriented optoelectronic devices with outstanding performance. As industry gets closer to the realization of nanoscale applications, there will be a need of people who are educated in nanoscience and nanotechnology. This project will involve postdoctoral, graduate, undergraduate, high school, and minority students from multidisciplinary backgrounds to work together on the development of a common platform. Read moreRead less
Power scaling of remote plasma sources for gallium nitride film growth with real-time monitoring of activated nitrogen species. Domestic, industrial and community lighting currently accounts for ~20% of the world's overall energy consumption. Commonly used incandescent lights are based on inefficient, century-old technologies. In contrast, light emitting diodes (LEDs) use ~80% less energy and last ~100 times longer. LED deployment will bring substantial economic and environmental benefits for Au ....Power scaling of remote plasma sources for gallium nitride film growth with real-time monitoring of activated nitrogen species. Domestic, industrial and community lighting currently accounts for ~20% of the world's overall energy consumption. Commonly used incandescent lights are based on inefficient, century-old technologies. In contrast, light emitting diodes (LEDs) use ~80% less energy and last ~100 times longer. LED deployment will bring substantial economic and environmental benefits for Australia and globally. Next generation high-efficiency LEDs for lighting, will operate with reduced energy consumption, thus contributing to reaching future national targets for CO2 emission reduction. This project will achieve reduced production cost of a key LED material, and will support Australia's leadership in a growing global semiconductor manufacturing industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560959
Funder
Australian Research Council
Funding Amount
$165,000.00
Summary
The Macquarie National Low Temperature Optoelectronic Thin Film Growth Facility. Funding is requested for an Australian facility for the growth of nitride and oxide thin films with in-situ optical analysis equipment for the monitoring of growth parameters. It is envisaged that this facility would be for the development of materials and device structures for photonic, electronic and optoelectronic applications. The facility will also provide a leading Australian source of these materials for fund ....The Macquarie National Low Temperature Optoelectronic Thin Film Growth Facility. Funding is requested for an Australian facility for the growth of nitride and oxide thin films with in-situ optical analysis equipment for the monitoring of growth parameters. It is envisaged that this facility would be for the development of materials and device structures for photonic, electronic and optoelectronic applications. The facility will also provide a leading Australian source of these materials for fundamental material studies utilising nuclear analysis and implantation technologies, high resolution X-ray diffraction, high spatial resolution micro-cathodoluminescence and other forms of analysis. Ex-situ optical analysis equipment is also requested for post-growth evaluation to compliment and evaluate the in-situ analysis.Read moreRead less
Self-organised complex ionised gas systems for ordered nanometre-scale assemblies. This proposal is to develop the physical principles of nano-scale assembly processes in complex plasmas. Novel approaches for tailoring the plasma-grown building blocks and controllable deposition of ordered nanoparticle arrays on nanopatterned solids are targeted. The fundamentals of the multi-scale dynamic processes will be elucidated and existing techniques for developing new materials and electronic/photonic d ....Self-organised complex ionised gas systems for ordered nanometre-scale assemblies. This proposal is to develop the physical principles of nano-scale assembly processes in complex plasmas. Novel approaches for tailoring the plasma-grown building blocks and controllable deposition of ordered nanoparticle arrays on nanopatterned solids are targeted. The fundamentals of the multi-scale dynamic processes will be elucidated and existing techniques for developing new materials and electronic/photonic devices will be advanced. The expected outcomes are highly relevant for the nano-materials and optoelectronic technologies, rapidly emerging areas of high-tech industries worldwide.Read moreRead less
Deterministic plasma-aided nanoassembly: from elementary processes to industry-grade nano- and biomaterials. This collaborative project aims to develop new approaches for the improved plasma-based synthesis of selected nano- and biomaterials that will comply with the relevant industry standards. It is based on extensive international research networking and will ultimately lead to a major breakthrough in highly-controlled plasma-aided synthesis of advanced functional materials and devices. The p ....Deterministic plasma-aided nanoassembly: from elementary processes to industry-grade nano- and biomaterials. This collaborative project aims to develop new approaches for the improved plasma-based synthesis of selected nano- and biomaterials that will comply with the relevant industry standards. It is based on extensive international research networking and will ultimately lead to a major breakthrough in highly-controlled plasma-aided synthesis of advanced functional materials and devices. The project outcomes will attract the interest of established and emerging industries in Australia, Singapore and other countries, and will be useful for the development of small high-tech companies in Australia. This project is ideally suited for training of early-career postdoctoral researchers and research students of competitive international standing.Read moreRead less
Plasma nanotools: bridging plasma physics and surface science. This project will herald a new frontier research area at the edge of plasma physics and surface science, secure and strengthen Australia's presence in newly emerging nanotechnology fields, reveal the superior potential of and raise the global high-tech market sentiment in plasma-aided nanofabrication of flat display panels, biosensors, nanoelectronic devices, smart nanomaterials, and other high-tech products. The outcomes will ultima ....Plasma nanotools: bridging plasma physics and surface science. This project will herald a new frontier research area at the edge of plasma physics and surface science, secure and strengthen Australia's presence in newly emerging nanotechnology fields, reveal the superior potential of and raise the global high-tech market sentiment in plasma-aided nanofabrication of flat display panels, biosensors, nanoelectronic devices, smart nanomaterials, and other high-tech products. The outcomes will ultimately lead to new environment-friendly and cost-efficient plasma-based technologies and nanofabrication and nanotooling industries in Australia. High profile of Australia-based research will be raised via a new network of international collaborations and low-cost involvement into forefront research programs.Read moreRead less
Proximity effects and new correlated phases in closely spaced quantum electronic devices. The aim of this project is to understand the interactions between quantum electronic devices when they are brought into close proximity. A detailed knowledge of these interactions and how to control them is important both for conintued miniaturisation in the semiconductor industry, and for the fundamental understanding of new quantum ground states. To achieve these goals new coupled device designs will be e ....Proximity effects and new correlated phases in closely spaced quantum electronic devices. The aim of this project is to understand the interactions between quantum electronic devices when they are brought into close proximity. A detailed knowledge of these interactions and how to control them is important both for conintued miniaturisation in the semiconductor industry, and for the fundamental understanding of new quantum ground states. To achieve these goals new coupled device designs will be engineered in collaboration with NTT's Basic Research Laboratories in Japan. Theses novel devices will be used to study fundamental correlations in quantum semiconductor systems, with the possibility of forming new correlated states of matter such as electron-hole superfluids.Read moreRead less
Electronics with spin: Investigating spin-dependent electrical properties of semiconductor nano-devices. Devices such as the integrated circuit and semiconductor lasers are products of basic research, and form the basis of new industries that have revolutionised society. Quantum physics was the science of the 20th century and is likely to become a key technology of the 21st century. This project will keep Australia at the forefront of the search for new and potentially commercially useful applic ....Electronics with spin: Investigating spin-dependent electrical properties of semiconductor nano-devices. Devices such as the integrated circuit and semiconductor lasers are products of basic research, and form the basis of new industries that have revolutionised society. Quantum physics was the science of the 20th century and is likely to become a key technology of the 21st century. This project will keep Australia at the forefront of the search for new and potentially commercially useful applications of quantum physics. The project will also provide training for Australian students to work in a cutting-edge semiconductor research facility, and involves linkages with leading international laboratories including Massey University (NZ), the University of Cambridge (UK), and NTT Basic Research Labs (Japan). Read moreRead less
Towards Quantum Electromechanical Devices with Semiconductor Nanowires. More importantly, semiconductor nanowires and nanorods represent a novel nanosystem being intensely researched world wide for applications in high efficiency solar cells, ultra bright light emitting diodes, single photon emitters, fast post CMOS wrap-gate field effect transistors, high efficiency thermoelectric devices and chemical sensing. The current proposal thus helps to ensure Australias forefront involvement in this qu ....Towards Quantum Electromechanical Devices with Semiconductor Nanowires. More importantly, semiconductor nanowires and nanorods represent a novel nanosystem being intensely researched world wide for applications in high efficiency solar cells, ultra bright light emitting diodes, single photon emitters, fast post CMOS wrap-gate field effect transistors, high efficiency thermoelectric devices and chemical sensing. The current proposal thus helps to ensure Australias forefront involvement in this quickly evolving and highly promising research field.Read moreRead less
Engineering Ultra-low Disorder Semiconductor Quantum Nanostructures. The multi-trillion dollar semiconductor industry drives the explosive growth in information technology that we have witnessed over the past 25 years. This proposal will provide a significant breakthrough by develop a new class of ultra low disorder 'quantum dot transistors' that will be of benefit to Australia's ongoing efforts in semiconductor nanotechnology and quantum information science, allowing us to play a role in the fu ....Engineering Ultra-low Disorder Semiconductor Quantum Nanostructures. The multi-trillion dollar semiconductor industry drives the explosive growth in information technology that we have witnessed over the past 25 years. This proposal will provide a significant breakthrough by develop a new class of ultra low disorder 'quantum dot transistors' that will be of benefit to Australia's ongoing efforts in semiconductor nanotechnology and quantum information science, allowing us to play a role in the future development of nanoscale and quantum electronics. This research program will bring together Australian researchers and students to work with leading international universities in the USA and New Zealand, and a leading Japanese industrial research facility - Nippon Telegraph and Telecommunications.Read moreRead less