Room Temperature Quantum Devices based on Spins in Organic Semiconductors:
Characterisation, Control and Development. Organic semiconductors are widely used in optoelectronic devices - recent work has also demonstrated that they contain coherent quantum spin states, even at room temperature. This project will use spin resonance and control techniques from quantum physics to determine the processes which limit coherence in these materials, determine ways to overcome these limitations, and then i ....Room Temperature Quantum Devices based on Spins in Organic Semiconductors:
Characterisation, Control and Development. Organic semiconductors are widely used in optoelectronic devices - recent work has also demonstrated that they contain coherent quantum spin states, even at room temperature. This project will use spin resonance and control techniques from quantum physics to determine the processes which limit coherence in these materials, determine ways to overcome these limitations, and then incorporate the materials into devices which exploit the power of these quantum systems at room-temperature. This project advances the prospect of ubiquitously incorporating quantum technologies into everyday applications, impacting fields from information storage to sensing.Read moreRead less
Electron transport in semiconductor nanowire devices - Setting two top nanoelectronics problems on the straight and narrow. This project will establish a new program to build electronic devices using tiny semiconductor nanowires. This project will contribute strongly to Australia's ongoing efforts in semiconductor nanotechnology and quantum information science, and allow Australia to play a leading role in the development of the next generation of electronics technologies.
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
Nanospintronics - Spin Transport in Semiconductor Nanostructures. The multi-billion 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 developing a new class of spintronic devices 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 nanosca ....Nanospintronics - Spin Transport in Semiconductor Nanostructures. The multi-billion 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 developing a new class of spintronic devices 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 provide training for Australian students in a cutting-edge semiconductor research facility, and involve linkages with leading international universities including Massey University (NZ), NTT Basic Research Labs (Japan) and the University of Bochum (Germany).Read moreRead less
Nanoscale electronic devices: bringing sample design, fabrication, test and theory together. 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 support 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 Aus ....Nanoscale electronic devices: bringing sample design, fabrication, test and theory together. 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 support 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 UK, Germany, the USA and New Zealand, allowing access to experimental facilities that simply do not exist in Australia. Read moreRead less
Hole nanoelectronics - new concepts for spintronic devices. This proposal will support a new basic research initiative in an area with enormous potential for the trillion dollar semiconductor industry - an industry that is well aware of the need to find a replacement for the conventional transistor beyond 2020. This research program will bring together Australian researchers and students to work with leading international universities in Germany and England, including the renowned Cavendish Labo ....Hole nanoelectronics - new concepts for spintronic devices. This proposal will support a new basic research initiative in an area with enormous potential for the trillion dollar semiconductor industry - an industry that is well aware of the need to find a replacement for the conventional transistor beyond 2020. This research program will bring together Australian researchers and students to work with leading international universities in Germany and England, including the renowned Cavendish Laboratory at Cambridge University. This project will position Australia to play a leading role in developing future quantum and spin-based technologies that have the potential to be as powerful over the next 50 years as conventional transistors have been over the past 50 years.Read moreRead less
Self-Assembled Semiconductor Nanowires: A New Platform for Spintronic Devices. The multi-billion dollar semiconductor industry drives the extraordinary growth in information technology that we have witnessed in recent decades. This Fellowship will establish a new program to build electronic devices using tiny semiconductor 'nanowires'. It draws on UNSW's international reputation in nanoelectronics research, strongly enhances Australia's existing investment in the growth of nanowires at ANU, an ....Self-Assembled Semiconductor Nanowires: A New Platform for Spintronic Devices. The multi-billion dollar semiconductor industry drives the extraordinary growth in information technology that we have witnessed in recent decades. This Fellowship will establish a new program to build electronic devices using tiny semiconductor 'nanowires'. It draws on UNSW's international reputation in nanoelectronics research, strongly enhances Australia's existing investment in the growth of nanowires at ANU, and will place Australia at the forefront of nanowire research on the international stage. This project will contribute strongly to Australia's ongoing efforts in semiconductor nanotechnology and quantum information science, and allow us to play a leading role in the development of next-generation computer technologies.Read moreRead less
Development of a molecular flash memory for long-term, extremely high-capacity, unpowered data storage. This collaborative project with INTEL will demonstrate an array of Flash-RAM molecular-memory cells capable, at room temperature, of storing a terabit of data on an area of 2 square mm. This data density is more than four orders of magnitude greater than any commercially available technology and unattainable by conventional silicon-based electronics. We will design and optimize the memory cel ....Development of a molecular flash memory for long-term, extremely high-capacity, unpowered data storage. This collaborative project with INTEL will demonstrate an array of Flash-RAM molecular-memory cells capable, at room temperature, of storing a terabit of data on an area of 2 square mm. This data density is more than four orders of magnitude greater than any commercially available technology and unattainable by conventional silicon-based electronics. We will design and optimize the memory cell, develop the synthesis method, synthesize arrays of the memory cells, and develop new molecular addressing technologies.Read moreRead less
Silicon-based molecular electronics. A whole new class of electronic devices based on single atoms and molecules is emerging. At this scale, the device components cease to behave like ordinary matter and novel quantum effects can be exploited. The tremendous potential for both device miniaturisation and the exploitation of quantum effects afforded by single-molecule devices has already been demonstrated. However, methods for assembling single-molecules into circuits and integrating them with con ....Silicon-based molecular electronics. A whole new class of electronic devices based on single atoms and molecules is emerging. At this scale, the device components cease to behave like ordinary matter and novel quantum effects can be exploited. The tremendous potential for both device miniaturisation and the exploitation of quantum effects afforded by single-molecule devices has already been demonstrated. However, methods for assembling single-molecules into circuits and integrating them with conventional technology remain elusive. Here, a strategy is presented for combining the functionality of organic, carbon-based components, with more conventional, silicon-based technology. The potential economic benefits for Australia of this hybrid carbon/silicon strategy are huge.Read moreRead less
Synchrotron radiation techniques applied to melting and resolidification at a nanometric scale. By delivering underpinning knowledge of melting characteristics of nanoparticles, the proposal seeks results that can lead to breakthrough applications in advanced materials engineering. Measurements of the liquid nanoparticle structure performed at the Australian Synchrotron are unprecedented and are thus likely to include the development of new methodology. National and international exposure of Aus ....Synchrotron radiation techniques applied to melting and resolidification at a nanometric scale. By delivering underpinning knowledge of melting characteristics of nanoparticles, the proposal seeks results that can lead to breakthrough applications in advanced materials engineering. Measurements of the liquid nanoparticle structure performed at the Australian Synchrotron are unprecedented and are thus likely to include the development of new methodology. National and international exposure of Australian science and the Australian Synchrotron will have both scientific and economic ramifications. Involvement of students will contribute to developing the local synchrotron knowledge base and is beneficial to the Australian synchrotron-research community as a whole.Read moreRead less