Novel graphene nanostructures: modelling, synthesis, fabrication and characterisation. As a key nanomaterial for future electronics, graphene is rapidly becoming one of the most promising frontier areas of nanotechnology throughout the world. This project aims to develop a new class of graphene nanostructures that hold great potential for large-scale applications in the next generation nanoelectronic devices, sensors, solar cells and light emitting devices. This project will significantly enhan ....Novel graphene nanostructures: modelling, synthesis, fabrication and characterisation. As a key nanomaterial for future electronics, graphene is rapidly becoming one of the most promising frontier areas of nanotechnology throughout the world. This project aims to develop a new class of graphene nanostructures that hold great potential for large-scale applications in the next generation nanoelectronic devices, sensors, solar cells and light emitting devices. This project will significantly enhance the international competitiveness of Australia in the areas of new materials and nanotechnology and will help place Australia at the forefront of nanotechnology. This project will produce high quality PhD students in nanotechnology.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0667994
Funder
Australian Research Council
Funding Amount
$1,000,000.00
Summary
National Nanolithography Facility. Nanotechnology is expected to have a major impact on quality of life and global economy. It is predicted to generate revenues as big as the ICT sector in 20 years time. The National Nanolithography Facility will enhance the Australian capability in the field of nanoscale science and technology. This will enable Australian researchers to achieve major impacts in many areas of nanotechnology with a strong potential impact on industry sectors such as computers, ....National Nanolithography Facility. Nanotechnology is expected to have a major impact on quality of life and global economy. It is predicted to generate revenues as big as the ICT sector in 20 years time. The National Nanolithography Facility will enhance the Australian capability in the field of nanoscale science and technology. This will enable Australian researchers to achieve major impacts in many areas of nanotechnology with a strong potential impact on industry sectors such as computers, communications, defence, health, bio-security. This facility has the potential for developing new technologies of fundamental as well as applied interest.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0238960
Funder
Australian Research Council
Funding Amount
$940,000.00
Summary
High Performance Semiconductor Micromachining Facility. The purpose of this project is to make available to the Australian semiconductor research community a facility to undertake specialist deposition and etching tasks needed for fabrication of next generation solar cells, microelectronics, optronics, and micro-electromechanical systems. The facility will have the flexibility to allow independent control of major process parameters, allowing development of new fabrication technologies which wi ....High Performance Semiconductor Micromachining Facility. The purpose of this project is to make available to the Australian semiconductor research community a facility to undertake specialist deposition and etching tasks needed for fabrication of next generation solar cells, microelectronics, optronics, and micro-electromechanical systems. The facility will have the flexibility to allow independent control of major process parameters, allowing development of new fabrication technologies which will be generic to a wide range of semiconductor materials. In particular, the facility will be unique in its ability to perform processes at low temperatures, and under conditions that allow optimisation of the deposition and etching processes, without compromising the performance of delicate devices or exceeding the maximum process temperature limitations found in many mainstream semiconductor materials technologies.Read moreRead less
New multiplexed optical read-out technologies for micromachined cantilever sensor arrays. Passive sensing of chemical and biological agents is an essential capability in fields as diverse as national security, agriculture, mining and medicine. In many cases, generic sensing (e.g. are there pesticides present) as well as specific sensing (which pesticide) are both important. While sensors based on micro-electromechanical systems (MEMS) have shown extremely high performance at low cost, they have ....New multiplexed optical read-out technologies for micromachined cantilever sensor arrays. Passive sensing of chemical and biological agents is an essential capability in fields as diverse as national security, agriculture, mining and medicine. In many cases, generic sensing (e.g. are there pesticides present) as well as specific sensing (which pesticide) are both important. While sensors based on micro-electromechanical systems (MEMS) have shown extremely high performance at low cost, they have been limited to detection of a specific substance. Success in this project will make low cost generic MEMS-based sensors a reality, allowing, for the first time, wide-spread use of sensitive sensing systems in applications such as farming, container transport security, general medical practice and national security.Read moreRead less
A novel approach to direct nanopatterning of silicon for advanced phase-changed devices. This project will exploit key research developments at ANU in the field of nanotechnology, specifically nanofabrication of entirely new devices. In particular, this work will be exploited by a new Australian high-tech company, WRiota, to produce novel silicon phase change devices. The instrumentation developments will be commercialized by a leading nanoindentation company and the materials and device-related ....A novel approach to direct nanopatterning of silicon for advanced phase-changed devices. This project will exploit key research developments at ANU in the field of nanotechnology, specifically nanofabrication of entirely new devices. In particular, this work will be exploited by a new Australian high-tech company, WRiota, to produce novel silicon phase change devices. The instrumentation developments will be commercialized by a leading nanoindentation company and the materials and device-related outcomes and IP will be retained and used by WRiota. This project will further provide valuable opportunities for a number of research students and ECRs to gain experience in both the industrial and academic worlds.Read moreRead less
Microelectronic Applications of Improved Silicon Light Emission. While semiconductor silicon chips have been the workhorse of the microelectronics revolution, more complex semiconductor materials have driven the communications revolution. Australian developments during 2001 have largely dispelled the myth that silicon is fundamentally a poor emitter of light. This project aims to build on this work by developing silicon light emitters suitable for integration into high density integrated circu ....Microelectronic Applications of Improved Silicon Light Emission. While semiconductor silicon chips have been the workhorse of the microelectronics revolution, more complex semiconductor materials have driven the communications revolution. Australian developments during 2001 have largely dispelled the myth that silicon is fundamentally a poor emitter of light. This project aims to build on this work by developing silicon light emitters suitable for integration into high density integrated circuits, adding a new dimension to the capabilities of these circuits, driving microelectronics and the information age to the next stage of development.Read moreRead less
Phase transitions in ultra-thin epitaxial polar oxide films. In this project we will utilize sophisticated thin film fabrication and characterization techniques( such as in-situ x-ray diffraction) and the most advanced computational materials science tools. Therefore this project will provide postgraduates and young researchers to cutting edge research, boosting the enormous potential of Australia in basic materials science. It brings together early career researchers with complimentary expert ....Phase transitions in ultra-thin epitaxial polar oxide films. In this project we will utilize sophisticated thin film fabrication and characterization techniques( such as in-situ x-ray diffraction) and the most advanced computational materials science tools. Therefore this project will provide postgraduates and young researchers to cutting edge research, boosting the enormous potential of Australia in basic materials science. It brings together early career researchers with complimentary expertise areas to interact with each other. It emphasizes cross-disciplinary research and exchange of research ideas across three continents; thus providing the ideal training ground for young researchers who are expected to make a major contribution to both, fundamental and applied research in the future.Read moreRead less
Theoretical and Numerical Analyses on Smart-Cut Technology. Smart-cut is an innovative and effective technique for fabricating high quality silicon-on-insulator structures which are widely used in the semiconductor and microelectronics industries. The quantification of the effects of processing parameters and the optimization of smart-cut process will be conducted in this project. The results are expected to make significant contributions to reducing cost, increasing efficiency and optimizing pr ....Theoretical and Numerical Analyses on Smart-Cut Technology. Smart-cut is an innovative and effective technique for fabricating high quality silicon-on-insulator structures which are widely used in the semiconductor and microelectronics industries. The quantification of the effects of processing parameters and the optimization of smart-cut process will be conducted in this project. The results are expected to make significant contributions to reducing cost, increasing efficiency and optimizing procedure by providing a theoretical and quantitative design methodology to improve the smart-cut technique. Consequently, the outcomes and results of the project will bring many benefits to and encourage further R&D in the semiconductor and microelectronics industries in Australia.Read moreRead less
Centre for Advanced Silicon Photovoltaics and Photonics. Silicon photovoltaics (Si PV) is a priority area within the Photon Science and Technology category. Multiple studies have identified PV solar electricity as the most promising option for a sustainable energy future, with Australia already at the forefront internationally in Si PV. The applicants recently have shown that insights from PV also may provide the key to the successful development of active Si photonic devices for integration i ....Centre for Advanced Silicon Photovoltaics and Photonics. Silicon photovoltaics (Si PV) is a priority area within the Photon Science and Technology category. Multiple studies have identified PV solar electricity as the most promising option for a sustainable energy future, with Australia already at the forefront internationally in Si PV. The applicants recently have shown that insights from PV also may provide the key to the successful development of active Si photonic devices for integration into microelectronics. The Centre's aims and expected outcomes are to strengthen this technological lead in Si PV while pioneering the development of active Si photonic devices for microelectronic integration, with economic, cultural and social benefits.Read moreRead less
Advanced microelectronic transistor structures for novel biosensor technology. This international, interdisciplinary team aims to develop an electronic biosensor technology that will significantly advance biomedical research to combat human disease. This is likely to have a major social impact on the community, improve health outcomes and generate substantial economic potential for the pharmaceutical industry. The principal benefit of this research will be the fabrication of electronic devices b ....Advanced microelectronic transistor structures for novel biosensor technology. This international, interdisciplinary team aims to develop an electronic biosensor technology that will significantly advance biomedical research to combat human disease. This is likely to have a major social impact on the community, improve health outcomes and generate substantial economic potential for the pharmaceutical industry. The principal benefit of this research will be the fabrication of electronic devices based on advanced materials, significantly reducing the time, the biological material used and the complexity of assessing human cell function. In addition to improving health through novel biosensor techniques, this technology is expected to lead to the creation of commercially important intellectual property.Read moreRead less