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
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
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
Novel Silicon-Based Photonic Devices. Silicon's pre-eminence in high-speed digital electronics does not extend to optoelectronics where the demand is for devices that can generate, guide, detect and process light. However, the properties of silicon are dramatically altered when it is reduced to nanometre dimensions. Advances in the understanding of such effects and in the fabrication and application of nanoscale silicon have provided the prospect of new and innovative Si-based photonic devices, ....Novel Silicon-Based Photonic Devices. Silicon's pre-eminence in high-speed digital electronics does not extend to optoelectronics where the demand is for devices that can generate, guide, detect and process light. However, the properties of silicon are dramatically altered when it is reduced to nanometre dimensions. Advances in the understanding of such effects and in the fabrication and application of nanoscale silicon have provided the prospect of new and innovative Si-based photonic devices, and of fully integrated electronic and photonic functionality. This project aims to extend the understanding of nanoscale silicon and to develop and prototype novel Si-based photonic devices based on this material.Read moreRead less
The Physical and Optical Properties of Self-Assembled Si Nanocrystals. The properties of nano-scale materials can differ significantly from those of their bulk counterparts. As such, they can provide materials with new and novel properties as well as proving a useful test of modern theories. An outstanding example of the significance of such effects is provided by quantum confined silicon structures, such as porous or nanocrystalline silicon, which exhibit luminescence efficiencies up to a milli ....The Physical and Optical Properties of Self-Assembled Si Nanocrystals. The properties of nano-scale materials can differ significantly from those of their bulk counterparts. As such, they can provide materials with new and novel properties as well as proving a useful test of modern theories. An outstanding example of the significance of such effects is provided by quantum confined silicon structures, such as porous or nanocrystalline silicon, which exhibit luminescence efficiencies up to a million times greater than bulk silicon. This project aims to understand the novel optical properties and interactions that underpin potential applications of this technologically important material.Read moreRead less
Formation of nanocrystals (or nanocrystals with core/shell structure) and applications for photonics, floating gate and magnetic memory. Materials that contain nanometre-sized crystallites of a second material can exhibit novel optical, electrical and magnetic properties that have direct technological application. However, it is often difficult to control the size and concentration of the small crystals using conventional synthesis techniques. This project will overcome these limitations by ex ....Formation of nanocrystals (or nanocrystals with core/shell structure) and applications for photonics, floating gate and magnetic memory. Materials that contain nanometre-sized crystallites of a second material can exhibit novel optical, electrical and magnetic properties that have direct technological application. However, it is often difficult to control the size and concentration of the small crystals using conventional synthesis techniques. This project will overcome these limitations by exploiting the unique properties of pulsed-laser heating to produce the crystals. It will also investigate the optical, electrical and magnetic properties of these new materials and asses their suitability for super-dense data storage, solid-state lighting and advanced detection systems.Read moreRead less
Switching mechanisms in nonvolatile resistive memory using high-k dielectrics. Growth in the use of portable electronic devices, such as cameras, phones and MP3 players has resulted in an increased demand for low-power, high-density, non-volatile memory (NVM). One class of such memories aims to use resistance changes in thin dielectric films as a means of storing information. This project aims to develop a better understanding of these devices and to develop new and innovative processes for co ....Switching mechanisms in nonvolatile resistive memory using high-k dielectrics. Growth in the use of portable electronic devices, such as cameras, phones and MP3 players has resulted in an increased demand for low-power, high-density, non-volatile memory (NVM). One class of such memories aims to use resistance changes in thin dielectric films as a means of storing information. This project aims to develop a better understanding of these devices and to develop new and innovative processes for controlling data storage. The project is based on collaboration between researchers at the ANU and Silanna, an Australian start-up company aiming to develop and commercialise such technology.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
Amorphisation of Semiconductor and Elemental Metallic Nanocrystals by Ion Irradiation. This proposal is consistent with Research Priority 3: Frontier Technologies for Building and Transforming Australian Industries and Priority Goals: Breakthrough Science, Advanced Materials and Frontier Technologies. We seek to understand and develop a unique methodology for modifying and tailoring the structure of semiconductor and metallic nanocrystals in ways not achievable within the bulk phase. Our res ....Amorphisation of Semiconductor and Elemental Metallic Nanocrystals by Ion Irradiation. This proposal is consistent with Research Priority 3: Frontier Technologies for Building and Transforming Australian Industries and Priority Goals: Breakthrough Science, Advanced Materials and Frontier Technologies. We seek to understand and develop a unique methodology for modifying and tailoring the structure of semiconductor and metallic nanocrystals in ways not achievable within the bulk phase. Our results and accompanying scientific insight will broaden the applicability of these materials in advanced technologies, enhance the national research profile, increase the domestic knowledge base and yield skilled, young scientists trained to utilize the Australian Synchrotron when commissioned in 2007.Read moreRead less