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
Self-assembled semiconductor nanocrystals as functional materials for microelectronics, optoelectronics and photonics. This project will study an important new class of nanoscale materials (semiconductor nanocrystals) with the aim of understanding the processes and mechanisms responsible for their structure and properties. It will have direct application to microelectronics, optoelectronics and photonics; will provide world-class training for Australia's future scientists and engineers in mater ....Self-assembled semiconductor nanocrystals as functional materials for microelectronics, optoelectronics and photonics. This project will study an important new class of nanoscale materials (semiconductor nanocrystals) with the aim of understanding the processes and mechanisms responsible for their structure and properties. It will have direct application to microelectronics, optoelectronics and photonics; will provide world-class training for Australia's future scientists and engineers in materials science and nanotechnology; and will further strengthen international scientific collaboration in these field.Read moreRead less
Charge transport and trapping in high-k dielectric films containing self-assembled nanocrystals. Growth in the use of portable electronic devices such as mobile phones, iPods, MP3-players and personal digital assistants (PDA's) has resulted in increased demand for low-power, high-density Flash memory. However, existing memory devices are difficult to scale to smaller dimensions and lower power without severely compromising reliability. This project will investigate the synthesis and properties ....Charge transport and trapping in high-k dielectric films containing self-assembled nanocrystals. Growth in the use of portable electronic devices such as mobile phones, iPods, MP3-players and personal digital assistants (PDA's) has resulted in increased demand for low-power, high-density Flash memory. However, existing memory devices are difficult to scale to smaller dimensions and lower power without severely compromising reliability. This project will investigate the synthesis and properties of a new class of materials that have the potential to overcome these limitations. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668510
Funder
Australian Research Council
Funding Amount
$180,240.00
Summary
Nanostructure Deposition Facility. New electronic devices and materials that exploit the properties of nanostructured surfaces are predicted to have a major impact on everyday life in areas such as information technology, biotechnology and healthcare. The Nanostructure Deposition Facility (NDF) is a unique facility, providing access to the highly specialised deposition equipment required to fabricate these important nanostructured surfaces from a variety of materials. The NFDL represents a major ....Nanostructure Deposition Facility. New electronic devices and materials that exploit the properties of nanostructured surfaces are predicted to have a major impact on everyday life in areas such as information technology, biotechnology and healthcare. The Nanostructure Deposition Facility (NDF) is a unique facility, providing access to the highly specialised deposition equipment required to fabricate these important nanostructured surfaces from a variety of materials. The NFDL represents a major new joint venture between seven Australian institutions and will provide these researchers with the essential tools for developing new electronic devices, biosensors, detectors and solar cells based on nanotechnology.Read moreRead less
Organic Field Effect Transistors for Biosensor Applications. The development of future Australian industries based on polymer electronics is tangible. The prohibitive establishment costs mean that there is effectively no Australian conventional semiconductor manufacturing industry. However, polymer electronic devices are simple to manufacture with low fabrication costs. As such, the commercial barriers to the development of an Australian soft electronics industry are much lower. Internationally, ....Organic Field Effect Transistors for Biosensor Applications. The development of future Australian industries based on polymer electronics is tangible. The prohibitive establishment costs mean that there is effectively no Australian conventional semiconductor manufacturing industry. However, polymer electronic devices are simple to manufacture with low fabrication costs. As such, the commercial barriers to the development of an Australian soft electronics industry are much lower. Internationally, soft electronics is developing apace and securing a soft electronics industry in Australia requires the urgent development of an Australian skill base in fabricating soft electronic devices. This project offers the opportunity of establishing a significant capability in soft electronic device fabrication.Read moreRead less
Microscopic Origin of Ferromagnetism of Diluted Magnetic Demiconductors. Spintronics based on the spin in addition to the charge of electrons is believed to revolutionize current microelectronics, which is approaching the end of the so-called silicon road map. Diluted magnetic semiconductors are required to achieve spintronics, just as silicon in microelectronics. This project aims to understand the microscopic origin of ferromagnetism of diluted magnetic semiconductors - a major obstacle toward ....Microscopic Origin of Ferromagnetism of Diluted Magnetic Demiconductors. Spintronics based on the spin in addition to the charge of electrons is believed to revolutionize current microelectronics, which is approaching the end of the so-called silicon road map. Diluted magnetic semiconductors are required to achieve spintronics, just as silicon in microelectronics. This project aims to understand the microscopic origin of ferromagnetism of diluted magnetic semiconductors - a major obstacle towards spintronics. This research, addressing an important problem in breakthrough science and frontier technologies, will not only expand Australia's knowledge base and research capability, but also help to build Australia's high value-added industries. Read moreRead less
Elastically controlled magnetoelectric transduction in thin film multilayers. Ferroelectric and ferromagnetic materials have attracted significant attention and exhibited potential in many applications such as storage memories, solid-state light sources and a range of smart chemical and biological sensors. This proposal seeks to investigate the behaviour of these materials in layered form, where an imposed mechanical traction induces novel combinations of ferroelectric and magnetic properties. T ....Elastically controlled magnetoelectric transduction in thin film multilayers. Ferroelectric and ferromagnetic materials have attracted significant attention and exhibited potential in many applications such as storage memories, solid-state light sources and a range of smart chemical and biological sensors. This proposal seeks to investigate the behaviour of these materials in layered form, where an imposed mechanical traction induces novel combinations of ferroelectric and magnetic properties. The fundamental understanding of the behaviour of these materials will help us develop new material systems with exciting possibilities in the design of advanced devices and sensors.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
Micro-patterning of fluoropolymer surfaces for electronic and biomaterials applications. Formation of micro-patterned structures on fluoropolymers including PTFE, FEP and PVDF will be performed using micro-contact printing techniques in combination with surface graft co-polymerisation; an innovative convergence of two emerging technologies. Surface modification and structures formed will be investigated using contact angle measurements and mapping, and surface analytical techniques (XPS and TOFS ....Micro-patterning of fluoropolymer surfaces for electronic and biomaterials applications. Formation of micro-patterned structures on fluoropolymers including PTFE, FEP and PVDF will be performed using micro-contact printing techniques in combination with surface graft co-polymerisation; an innovative convergence of two emerging technologies. Surface modification and structures formed will be investigated using contact angle measurements and mapping, and surface analytical techniques (XPS and TOFSIMS). Processing methodologies will be identified which allow formation of micrometre scale tracks, and selected area deposition of sensor films and reactive biomaterials. Trial device fabrication will be undertaken using conditions and device structures similar to those required for production of diagnostic sensors and arrays, and polymer-based electronic devices.Read moreRead less
Atomic-Scale Identification of Amorphization and Relaxation Processes in Compound Semiconductors. We seek a fundamental understanding of the processes that govern implantation-induced structure, at the nanometer scale, in the compound semiconductors used in photonic device fabrication. Since implantation-induced disorder limits the performance of such devices, the proposed project is of substantial technological significance and national benefit. The Photon Science techniques of perturbed angu ....Atomic-Scale Identification of Amorphization and Relaxation Processes in Compound Semiconductors. We seek a fundamental understanding of the processes that govern implantation-induced structure, at the nanometer scale, in the compound semiconductors used in photonic device fabrication. Since implantation-induced disorder limits the performance of such devices, the proposed project is of substantial technological significance and national benefit. The Photon Science techniques of perturbed angular correlation and extended x-ray absorption fine structure spectroscopy will be used to identify the mechanism of amorphisation and relaxation in order to enable more effective exploitation of compound semiconductors in advanced telecommunications systems.Read moreRead less