Exploring the Fundamentals of Atomically Precise Manufacturing with Scanning Probe Microscopes. Over the past five years, Australian researchers have pioneered the development of a new method for fabricating electrical devices in silicon with atomic precision. By partnering with the world leader in nanotechnology manufacturing, these same researchers now have an opportunity to extend Australia's early lead in this area. The proposed research will lead to new capabilities for Australia within the ....Exploring the Fundamentals of Atomically Precise Manufacturing with Scanning Probe Microscopes. Over the past five years, Australian researchers have pioneered the development of a new method for fabricating electrical devices in silicon with atomic precision. By partnering with the world leader in nanotechnology manufacturing, these same researchers now have an opportunity to extend Australia's early lead in this area. The proposed research will lead to new capabilities for Australia within the growing field of electro-mechanical devices. It will strengthen and broaden Australia's leadership in atomic-scale device fabrication in silicon. It will assist world-leading Australian researchers to evaluate and prioritise the commercial potential of their technologies.Read moreRead less
Diamond based single spin detector. It is expected that the development of the diamond based spin detector will further enhance Australia's international reputation as a significant contributor to the broad field of nanotechnology. The spin detection technology will have many applications in a variety of fields that rely on nanoscale precision measurement of single quantum systems.
Single spin detection will also be a pivotal tool in the push to produce quantum information technologies, a fi ....Diamond based single spin detector. It is expected that the development of the diamond based spin detector will further enhance Australia's international reputation as a significant contributor to the broad field of nanotechnology. The spin detection technology will have many applications in a variety of fields that rely on nanoscale precision measurement of single quantum systems.
Single spin detection will also be a pivotal tool in the push to produce quantum information technologies, a field that has been invested in heavily by the Australian government. This device will significantly enhance the potential success of a range of projects related to such nanoscale science.
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Diamond Single Photon Source. This project will enhance Australia's international profile in the area of quantum technology and will link, for the first time, diamond single photon capability with fibre optics technology, building on the strengths of both fields. The innovative steps in photonics and materials science which we are initiating place us in a unique position to exploit the emerging niche market for single photon sources. A provisional patent application for this technology is bein ....Diamond Single Photon Source. This project will enhance Australia's international profile in the area of quantum technology and will link, for the first time, diamond single photon capability with fibre optics technology, building on the strengths of both fields. The innovative steps in photonics and materials science which we are initiating place us in a unique position to exploit the emerging niche market for single photon sources. A provisional patent application for this technology is being lodged by the applicant and University of Melbourne colleagues in conjunction with QUCOR Pty Ltd. Success in researching and developing this device will help consolidate Australia's reputation as a global contributor to leading edge science and technology. Read moreRead less
Three Dimensional Integrated Circuits. Pushing the boundaries of current silicon fabrication technology, this proposal will investigate the possibilities of new 3D architectures to ensure that Australia remains at the forefront of world-wide research into atomic-scale electronics. It creates an important link to the latest technologies in atomistic device modelling in the US, developed at Texas Instruments. More importantly, by anticipating the problems that electronic device manufacturers are c ....Three Dimensional Integrated Circuits. Pushing the boundaries of current silicon fabrication technology, this proposal will investigate the possibilities of new 3D architectures to ensure that Australia remains at the forefront of world-wide research into atomic-scale electronics. It creates an important link to the latest technologies in atomistic device modelling in the US, developed at Texas Instruments. More importantly, by anticipating the problems that electronic device manufacturers are currently facing, and will face over their long-term horizons, the proposed research also seeks to provide Australia with a chance to lift its involvement in the multi-trillion dollar global semiconductor industry.Read moreRead less
Atomic Electronics: Precompetitive Research for the Global Semiconductor Industry. The demonstration in Australia that electronic devices in silicon can be fabricated at the atomic-scale has provided a vision for global semiconductor manufacturers. By engaging with leading US companies to tackle the problems industry faces as it attempts to reach this scale, this Fellowship will ensure that Australia remains at the forefront of growing world-wide research into atomic-scale electronics. Equally ....Atomic Electronics: Precompetitive Research for the Global Semiconductor Industry. The demonstration in Australia that electronic devices in silicon can be fabricated at the atomic-scale has provided a vision for global semiconductor manufacturers. By engaging with leading US companies to tackle the problems industry faces as it attempts to reach this scale, this Fellowship will ensure that Australia remains at the forefront of growing world-wide research into atomic-scale electronics. Equally important, by anticipating the problems that electronic device manufacturers are currently facing, and will face over their long-term horizons, the proposed research seeks to provide Australia with a long-term opportunity to lift its involvement in the multi-trillion dollar global semiconductor industry.Read moreRead less
The best of both worlds: electrically detected optical spectroscopy at the single atom limit. One atom, one photon, one electron, in a silicon crystal. We will demonstrate a novel technique to detect the absorption of light by a single atom, in the most significant environment for nanoelectronics and photovoltaics. Our technique will help unravel how light is turned into electricity at the most microscopic and fundamental level.
Insight and understanding in Rare-Earth magnetism. Today's technologically driven society relies on magnetic materials to an extent unimaginable even as recently as 20 years ago. Rare-earth transition-metal intermetallics are among the most important magnetic materials, providing the World's strongest magnet with extensive applications. Despite these impressive technological and commercial developments numerous aspects of rare-earth magnetism remain to be developed and resolved. The two innovati ....Insight and understanding in Rare-Earth magnetism. Today's technologically driven society relies on magnetic materials to an extent unimaginable even as recently as 20 years ago. Rare-earth transition-metal intermetallics are among the most important magnetic materials, providing the World's strongest magnet with extensive applications. Despite these impressive technological and commercial developments numerous aspects of rare-earth magnetism remain to be developed and resolved. The two innovative topics we shall research are the critical interplay between the rare-earth and transition-metal sublattices in ternary compounds, enabling us to understand complex compounds, and exploration of a set of quaternary compounds we have recently discovered, thus opening new areas of rare-earth magnetism.Read moreRead less
Strong electron correlations in quantum materials. The project will fundamentally advance the knowledge base towards the development of novel quantum materials. The project will reveal mechanisms of strong electron correlations and develop methods to use these correlations to enhance desirable properties of materials.
Discovery Early Career Researcher Award - Grant ID: DE210100291
Funder
Australian Research Council
Funding Amount
$414,000.00
Summary
Conferring life-like functions to protocells. For life to have arisen, simple self-assembled chemicals must have performed key life-like functions. This project aims to generate new knowledge in the fields of soft condensed matter physics and astrobiology by understanding how primitive life could have obtained nutrients and completed “cell” division without proteins. This ambitious goal is expected to not only contribute towards understanding the origins of life, one of the grand challenges in s ....Conferring life-like functions to protocells. For life to have arisen, simple self-assembled chemicals must have performed key life-like functions. This project aims to generate new knowledge in the fields of soft condensed matter physics and astrobiology by understanding how primitive life could have obtained nutrients and completed “cell” division without proteins. This ambitious goal is expected to not only contribute towards understanding the origins of life, one of the grand challenges in science, but also to elucidate principles in membrane biophysics and self-assembly. The fundamental scientific findings will be applied to making responsive capsules that can confer advanced functionalities to soft materials. Several international collaborations are anticipated.Read moreRead less
Bioelectronic logic. This project aims to understand ion-electron interactions relevant to bioelectronics, and create transducing interfaces. Bioelectronics is a frontier field which aims to connect biological systems with modern electronics and so create biomedical devices. Transducing ion and electron signals using a biocompatible functional interface is difficult since ion and electron physics are different. By combining individual transducers, this project intends to demonstrate ground-break ....Bioelectronic logic. This project aims to understand ion-electron interactions relevant to bioelectronics, and create transducing interfaces. Bioelectronics is a frontier field which aims to connect biological systems with modern electronics and so create biomedical devices. Transducing ion and electron signals using a biocompatible functional interface is difficult since ion and electron physics are different. By combining individual transducers, this project intends to demonstrate ground-breaking bioelectronic logic capable of interface-level processing. The stretch goal is to test this new logic with a biological neuronal model. The project could deliver new science and interfacing elements to integrate tissue and circuitry, and demonstrate these in a real biological model.Read moreRead less