Redesigning the transistor at the atomic-scale. Australian researchers have a world-wide leadership position in atomic-scale electronics. Through the development of powerful new fabrication technologies, Australian scientists are now poised to uncover the physical properties of electronic systems operating on the atomic-scale. This research will be internationally significant, providing ongoing international profile for Australian science. Perhaps more significantly, it will also lay the groundw ....Redesigning the transistor at the atomic-scale. Australian researchers have a world-wide leadership position in atomic-scale electronics. Through the development of powerful new fabrication technologies, Australian scientists are now poised to uncover the physical properties of electronic systems operating on the atomic-scale. This research will be internationally significant, providing ongoing international profile for Australian science. Perhaps more significantly, it will also lay the groundwork for future miniaturisation - and redesign - of the conventional transistor. Over the longer-term, it offers an opportunity for Australia to lift its involvement in the multi-trillion dollar global semiconductor industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0454224
Funder
Australian Research Council
Funding Amount
$1,234,800.00
Summary
Scanning probe facility for atomic-scale device fabrication in silicon and its integration with molecular electronics. This application will establish a unique scanning probe facility to launch two major new initiatives in electronic device fabrication in Australia: (i) atomic-scale device fabrication in silicon and (ii) the integration with molecular electronics. The revolutionary features of the Nanoprobe system exploits recent advances in scanning probe techniques to allow for the first time ....Scanning probe facility for atomic-scale device fabrication in silicon and its integration with molecular electronics. This application will establish a unique scanning probe facility to launch two major new initiatives in electronic device fabrication in Australia: (i) atomic-scale device fabrication in silicon and (ii) the integration with molecular electronics. The revolutionary features of the Nanoprobe system exploits recent advances in scanning probe techniques to allow for the first time fully functional silicon and hybrid silicon-molecular electronic devices to be fabricated and tested at the atomic-scale. Such a facility will draw together a host of experienced researchers in this emerging field enabling Australia to actively lead the development of this new technology at its early stages.Read moreRead less
Fundamental conduction mechanisms in atomic-scale silicon devices. This proposal will ensure that Australia remains at the forefront of worldwide research into atomic-scale electronics. It links leading nanotechnologists from Canada and Italy to a dynamic and growing Australian team, which already has strong collaborations with researchers in the UK, the US, Japan, and Taiwan. In the long-run, Australia stands to benefit indirectly from the research as it is a significant user of semiconductors ....Fundamental conduction mechanisms in atomic-scale silicon devices. This proposal will ensure that Australia remains at the forefront of worldwide research into atomic-scale electronics. It links leading nanotechnologists from Canada and Italy to a dynamic and growing Australian team, which already has strong collaborations with researchers in the UK, the US, Japan, and Taiwan. In the long-run, Australia stands to benefit indirectly from the research as it is a significant user of semiconductors across all major industries. More importantly, by anticipating the problems that electronic device manufacturers 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-scale Devices in Silicon - the Ultimate Limit of Microelectronics. Miniaturisation is the driving force behind the microelectronics industry, but beyond 2015 there is no known route to reduce device sizes below 10nm. The Fellowship will launch a major new initiative for the fabrication of silicon electronic devices at the atomic-scale (0.1nm). The project will exploit recent advances in scanning probe techniques to develop smaller and faster conventional transistors, nanoscale integrated ....Atomic-scale Devices in Silicon - the Ultimate Limit of Microelectronics. Miniaturisation is the driving force behind the microelectronics industry, but beyond 2015 there is no known route to reduce device sizes below 10nm. The Fellowship will launch a major new initiative for the fabrication of silicon electronic devices at the atomic-scale (0.1nm). The project will exploit recent advances in scanning probe techniques to develop smaller and faster conventional transistors, nanoscale integrated circuits, and address device reproducibility at this scale. This will extend Australia's early lead in atomic-scale silicon electronics to the stage where interested industry partners can evaluate it commercially in a way that will maximise benefits to Australia.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
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
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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668302
Funder
Australian Research Council
Funding Amount
$210,000.00
Summary
Floating-zone Crystal Growth Facility. Optical floating-zone furnaces are powerful and efficient tools for the discovery and characterisation of new materials. They are widely used in the solid-state chemistry, condensed-matter physics, materials science, and engineering communities. This optical floating-zone furnace, the first in Australia, will support and encourage the growing number of local researchers in these fields. It will allow them to take much better advantage of the new research re ....Floating-zone Crystal Growth Facility. Optical floating-zone furnaces are powerful and efficient tools for the discovery and characterisation of new materials. They are widely used in the solid-state chemistry, condensed-matter physics, materials science, and engineering communities. This optical floating-zone furnace, the first in Australia, will support and encourage the growing number of local researchers in these fields. It will allow them to take much better advantage of the new research reactor and synchrotron being constructed in Australia by maximising their ability to grow crystals of technologically and scientifically important materials, particularly electronic and magnetic materials, for fundamental and applied research at those facilities.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347797
Funder
Australian Research Council
Funding Amount
$263,000.00
Summary
A Versatile High-resolution X-ray Diffractometer for Materials Research. The aim of this project is to establish a state-of-the-art triple-axis x-ray diffraction facility capable of non-destructively analysing complex semiconductor materials and structures investigated by all Australian semiconductor-growing groups. Growers and device engineers will be able to control growth processes accurately and correlate device performance with structural analysis. Modern triple-axis instruments can also b ....A Versatile High-resolution X-ray Diffractometer for Materials Research. The aim of this project is to establish a state-of-the-art triple-axis x-ray diffraction facility capable of non-destructively analysing complex semiconductor materials and structures investigated by all Australian semiconductor-growing groups. Growers and device engineers will be able to control growth processes accurately and correlate device performance with structural analysis. Modern triple-axis instruments can also be used for high-resolution texture analysis and surface reflectivity measurements on numerous types of materials. Thus chemists, geologists, and materials scientists with interests outside of the semiconductor growth community will gain substantial benefit from this instrument for the investigation of materials of technological and economic importance.Read moreRead less