Laser Spectroscopy of Molecular Electronic Components. Electronic devices such as computer memory have been getting smaller and smaller for decades, yet soon devices will need to be constructed from single molecules. Single molecules behave very differently to copper conductors and silicon chips. To understand the behaviour of molecular electronic devices such as molecular wires, switches and diodes, one needs to isolate them under rigorously reproducable conditions. We will study molecular elec ....Laser Spectroscopy of Molecular Electronic Components. Electronic devices such as computer memory have been getting smaller and smaller for decades, yet soon devices will need to be constructed from single molecules. Single molecules behave very differently to copper conductors and silicon chips. To understand the behaviour of molecular electronic devices such as molecular wires, switches and diodes, one needs to isolate them under rigorously reproducable conditions. We will study molecular electronic devices in this way, providing rigorous support to Australia's growing expertise in this field.Read moreRead less
Development of room temperature diluted magnetic semiconductors for spintronics devices application. Semiconductor spintronics is very likely to have a significant impact on future generations of devices. Until recently, Australian research groups have played a minor role in the field. The proposed program will lead to new discoveries or fundamental advances within semiconductor spintronics or have substantial impact on the progress in this field. The accomplishments of this project can great ....Development of room temperature diluted magnetic semiconductors for spintronics devices application. Semiconductor spintronics is very likely to have a significant impact on future generations of devices. Until recently, Australian research groups have played a minor role in the field. The proposed program will lead to new discoveries or fundamental advances within semiconductor spintronics or have substantial impact on the progress in this field. The accomplishments of this project can greatly increase the scientific understanding of diluted magnetic semiconductors and expand Australia's knowledge base in research in these materials. This program can also be an education platform to provide a number of scientific talents for Australia by intensively training high quality postgraduates at the international level.Read moreRead less
Double Exposure Photoresists for the 32 and 22 nm Lithographic Nodes. The semiconductor industry is one of the largest world-wide, with annual revenue of $220B and employing over 1.5M people around the world. This project provides a unique opportunity for development within Australia of significant expertise in the field of double exposure lithography. The novel photoactive polymeric films to be developed are expected to support the next generation of microchips. A major outcome of this project ....Double Exposure Photoresists for the 32 and 22 nm Lithographic Nodes. The semiconductor industry is one of the largest world-wide, with annual revenue of $220B and employing over 1.5M people around the world. This project provides a unique opportunity for development within Australia of significant expertise in the field of double exposure lithography. The novel photoactive polymeric films to be developed are expected to support the next generation of microchips. A major outcome of this project will be establishment of Australia as a world-leader in this rapidly expanding field. Furthermore the technology can be applied broadly to many printing technologies.Read moreRead less
Advanced Lithographic Solutions using Block Copolymers: Integrating Self Assembly and Lithography. The semiconductor industry is one of the largest world-wide, with annual revenue of $220B and employing over 1.5M people around the world. This project provides a unique opportunity for development within Australia of significant expertise in the field of self assembly in photolithography. Plastics with tailored properties will be made and used to develop novel processes to reduce the defectivity i ....Advanced Lithographic Solutions using Block Copolymers: Integrating Self Assembly and Lithography. The semiconductor industry is one of the largest world-wide, with annual revenue of $220B and employing over 1.5M people around the world. This project provides a unique opportunity for development within Australia of significant expertise in the field of self assembly in photolithography. Plastics with tailored properties will be made and used to develop novel processes to reduce the defectivity in integrated circuit manufacture. The ultimate benefit will be faster and more energy efficient microprocessors. A major outcome of this project will be establishment of Australia as a world-leader in this rapidly expanding field. Furthermore, the technology can be applied broadly to many other applications such as high density data storage.Read moreRead less
Quantum coherence and many-body interactions in inorganic and organic nanoscale electronic devices. The multi-trillion dollar semiconductor industry drives the explosive growth in information technology that we have witnessed over the past 25 years. Although Australia is not presently a major player in the industry, this proposal will enable Australia to play a role in its future development of nanoscale electronics, both in conventional (inorganic) semiconductor devices, and in new (organic) de ....Quantum coherence and many-body interactions in inorganic and organic nanoscale electronic devices. The multi-trillion dollar semiconductor industry drives the explosive growth in information technology that we have witnessed over the past 25 years. Although Australia is not presently a major player in the industry, this proposal will enable Australia to play a role in its future development of nanoscale electronics, both in conventional (inorganic) semiconductor devices, and in new (organic) device technologies based on carbon nanotubes. This research program will allow Australian researchers and students to work both with leading international universities (Cambridge (UK) and Copenhagen (Denmark), and a leading Japanese industrial research facility - Nippon Telegraph and Telecommunications.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
DNA Directed Nanofabrication - A novel, universal, highly parallel bottom-up assembly approach. This proposal aims to provide a nanofabrication method that has the potential to strongly impact every aspect of science - from fundamental research to commercial applications by providing a universal, simple low-cost tool to build nanostructures to order. The basic properties of these structures will be studied prior to their integration into new applications. We will be providing a solution to a b ....DNA Directed Nanofabrication - A novel, universal, highly parallel bottom-up assembly approach. This proposal aims to provide a nanofabrication method that has the potential to strongly impact every aspect of science - from fundamental research to commercial applications by providing a universal, simple low-cost tool to build nanostructures to order. The basic properties of these structures will be studied prior to their integration into new applications. We will be providing a solution to a bottleneck that currently limits the scientific advancement and commercial exploitation of nanotechnology. Our proposal describes a 'Nanoassembly' technique, considered by the ARC as Frontier Technologies for Building and Transforming Australian Industries (ARC priority area 3). Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989615
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Melbourne Platform for Surface Characterisation of Structured Materials. The Australian economy is gradually expanding its manufacturing base through the development of the nanotechnology and biotechnology sectors. This will lead to production of a more diverse range of elaborately transformed goods. A key contributor to these export opportunities will be the nanotechnology sector since at the present time no country has a real nanotechnology based economy and there are many niche markets availa ....Melbourne Platform for Surface Characterisation of Structured Materials. The Australian economy is gradually expanding its manufacturing base through the development of the nanotechnology and biotechnology sectors. This will lead to production of a more diverse range of elaborately transformed goods. A key contributor to these export opportunities will be the nanotechnology sector since at the present time no country has a real nanotechnology based economy and there are many niche markets available for smaller countries such as Australia. This proposal helps to build quality control and characterisation infrastructure that will facilitate prototyping and design of nanoscale devices and sensors for next generation manufacturing.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882878
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
Facility for imaging, manipulation and measurement of molecular-scale quantum materials. The development of functional electronic devices relies on understanding how properties on the atomic-scale influence the performance of new device materials. We will develop the capability to image and manipulate surfaces, and enable new protocols for probing the quantum properties of a wide range of materials that cannot currently be accessed at the molecular-level. By facilitating studies of important eme ....Facility for imaging, manipulation and measurement of molecular-scale quantum materials. The development of functional electronic devices relies on understanding how properties on the atomic-scale influence the performance of new device materials. We will develop the capability to image and manipulate surfaces, and enable new protocols for probing the quantum properties of a wide range of materials that cannot currently be accessed at the molecular-level. By facilitating studies of important emerging materials such as diamond, fullerenes and magnetic molecules, the facility aims to place Australia at the forefront of new areas of surface and device science, and to develop new devices for quantum metrology, information and molecular detection within frontier quantum industries.Read moreRead less