Towards a high density silicon phase change memory device. This project builds upon our exciting recent findings that amorphous silicon can be transformed to a conducting crystalline phase following small-scale indentation. Furthermore the process is reversible as re-indentation can induce a transformation back to insulating amorphous silicon. This process appears to occur in extremely small (nanoscale) volumes of silicon. We plan to explore the viability of exploiting this behaviour to develo ....Towards a high density silicon phase change memory device. This project builds upon our exciting recent findings that amorphous silicon can be transformed to a conducting crystalline phase following small-scale indentation. Furthermore the process is reversible as re-indentation can induce a transformation back to insulating amorphous silicon. This process appears to occur in extremely small (nanoscale) volumes of silicon. We plan to explore the viability of exploiting this behaviour to develop an entirely new information storage system: a high-density silicon phase change memory. This project aims to study small-scale transformation behaviour in silicon and to design demonstrator memory devices based on both micro-electromechanical systems and solid state technologies.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453963
Funder
Australian Research Council
Funding Amount
$546,352.00
Summary
An integrated nanoscale fabrication, manipulation and characterisation facility. The fabrication of ordered structures at the nanometre scale is essential if the aspirations of nanotechnology are to be achieved. Understanding the fundamental nanoscience controlling the fabrication and operation of such devices is vital. The combination of instruments requested for this project will allow the construction of arrays of nanoparticles, their precise characterisation and the direct measurement of i ....An integrated nanoscale fabrication, manipulation and characterisation facility. The fabrication of ordered structures at the nanometre scale is essential if the aspirations of nanotechnology are to be achieved. Understanding the fundamental nanoscience controlling the fabrication and operation of such devices is vital. The combination of instruments requested for this project will allow the construction of arrays of nanoparticles, their precise characterisation and the direct measurement of interpartice and intermolecular forces at the pN level. Parallel computational chemistry and state of the art experiments will lead to the optimised design of nanostructures that will be applied in diverse areas, including mineral processing, biosensors, photonics, magnetic storage and catalysis.Read moreRead less
Nanoindentation-induced Phase Transformations and Physical Property Changes in Semiconductors. The motivation for this study derives from recent findings of intriguing phase and structural changes induced in semiconductors under a small indenter when it is pressed into the surface. Using an array of sophisticated techniques, in this study we plan to explore for the first time the structural changes that can be induced in semiconductors on the nanoscale and to study what novel properties, partic ....Nanoindentation-induced Phase Transformations and Physical Property Changes in Semiconductors. The motivation for this study derives from recent findings of intriguing phase and structural changes induced in semiconductors under a small indenter when it is pressed into the surface. Using an array of sophisticated techniques, in this study we plan to explore for the first time the structural changes that can be induced in semiconductors on the nanoscale and to study what novel properties, particularly electrical, such nanoscale regions may have. Detailed nanoindentation studies will focus on understanding and exploiting deformation of silicon, to open up an exciting prospect: the development of an entirely new, ultra-high-density information storage process.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL0992306
Funder
Australian Research Council
Funding Amount
$2,753,841.00
Summary
Nanowire Quantum Structures for Next Generation Optoelectronics. This innovative project on quantum nanowire optoelectronics will bring international kudos to Australian science in a hot research area of immense international interest, allow us to build new capabilities in nanotechnology, strengthen international linkages and lead to training of a world class high tech work force for Australian industries. This project has the potential to lead to fundamental discoveries and technologies of imm ....Nanowire Quantum Structures for Next Generation Optoelectronics. This innovative project on quantum nanowire optoelectronics will bring international kudos to Australian science in a hot research area of immense international interest, allow us to build new capabilities in nanotechnology, strengthen international linkages and lead to training of a world class high tech work force for Australian industries. This project has the potential to lead to fundamental discoveries and technologies of immense international and industrial interest. In addition to high impact publications, this project has the potential to lead to high tech start up companies and patentable technologies of benefit to Australian industry. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453974
Funder
Australian Research Council
Funding Amount
$113,190.00
Summary
T-ray factory: a new Australian source of strong, pulsed, broadband, terahertz radiation. Australian scientists and engineers require immediate access to frontier T-ray (terahertz radiation) technology to solve pressing current problems in semiconductor nanostructures and emerging problems in fields as diverse as biophysics and national security. Recent innovations now make practical the production of bursts of terahertz radiation by applying ultrafast optical pulses to photoconductive or elect ....T-ray factory: a new Australian source of strong, pulsed, broadband, terahertz radiation. Australian scientists and engineers require immediate access to frontier T-ray (terahertz radiation) technology to solve pressing current problems in semiconductor nanostructures and emerging problems in fields as diverse as biophysics and national security. Recent innovations now make practical the production of bursts of terahertz radiation by applying ultrafast optical pulses to photoconductive or electro-optic media, facilitating unparalleled time-resolved spectroscopy and imaging. The state-of-the-art equipment to be purchased and installed at Wollongong will enhance the existing excellent terahertz infrastructure (unique spectrometers, optically-pumped molecular laser) and efficiently service researchers in the dynamic Sydney (UTS, UNSW) - Wollongong (UoW) - Canberra (ANU) corridor.Read moreRead less
Tailoring the Shape, Size and Orientation of Metal Nanocrystals via Swift Heavy Ion Irradiation. This proposal is consistent with National Research Priority 3: Frontier Technologies for Building and Transforming Australian Industries and the Priority Goals: Breakthrough Science, Advanced Materials and Frontier Technologies. Our ability to tailor the shape, size and orientation of metal nanocrystals will broaden the domestic knowledge base, enhance the national research profile and train young ....Tailoring the Shape, Size and Orientation of Metal Nanocrystals via Swift Heavy Ion Irradiation. This proposal is consistent with National Research Priority 3: Frontier Technologies for Building and Transforming Australian Industries and the Priority Goals: Breakthrough Science, Advanced Materials and Frontier Technologies. Our ability to tailor the shape, size and orientation of metal nanocrystals will broaden the domestic knowledge base, enhance the national research profile and train young scientists, particularly in the use of two national facilities: the Australian Synchrotron and the ANU Heavy-Ion Accelerator Facility. Furthermore, domestic capabilities in materials characterisation and nanotechnology will be bolstered, state-of-the-art domestic industry will be enhanced and new technological applications will be enabled.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0454008
Funder
Australian Research Council
Funding Amount
$340,962.00
Summary
Multi-function high resolution-analytical scanning electron microscope facility. The aim of this proposal is to establish a high resolution electron microscope facility as part of a comprehensive materials characterisation infrastructure required to support Swinburne's expanding activities in nanotechnology. A high resolution SEM in conjunction with an upgrade of the current SEM will provide advanced instrumentation for nanoscale imaging, analysis and manipulation of materials. The proposed faci ....Multi-function high resolution-analytical scanning electron microscope facility. The aim of this proposal is to establish a high resolution electron microscope facility as part of a comprehensive materials characterisation infrastructure required to support Swinburne's expanding activities in nanotechnology. A high resolution SEM in conjunction with an upgrade of the current SEM will provide advanced instrumentation for nanoscale imaging, analysis and manipulation of materials. The proposed facility will create new opportunities for collaborative programs with local and overseas researcher and will facilitate rapid progress in research programs across the entire University in particular those related to two ARC Centres of Excellence in which the University is a core partner.Read moreRead less
Nonlinear nanophotonics. This project will support world-leading research in nonlinear nanophotonics. It will develop theoretically and demonstrate experimentally novel concepts for confining and manipulating light in specially designed structures, making an essential step towards the creation of nanoscaled optical devices for storage, memory, and sensing. These developments will underpin the next generation of high-performance optical networks promising to revolutionize global communications. T ....Nonlinear nanophotonics. This project will support world-leading research in nonlinear nanophotonics. It will develop theoretically and demonstrate experimentally novel concepts for confining and manipulating light in specially designed structures, making an essential step towards the creation of nanoscaled optical devices for storage, memory, and sensing. These developments will underpin the next generation of high-performance optical networks promising to revolutionize global communications. This research program will keep Australia at the forefront of international research and provide training for students in breakthrough applications of nanophotonics and nanotechnology, contributing to the uptake of frontier technologies by Australian industries.Read moreRead less
All-optical technologies, nanophotonics, and metamaterials. This program will support a world-leading team in nanophotonics and metamaterials. It will introduce and demonstrate novel concepts for manipulating optical pulses in specially designed nanoscale structures, making an essential step towards the creation of all-optical devices which perform fast switching and processing of optical signals. These developments will underpin the next generation of high-performance networks promising to revo ....All-optical technologies, nanophotonics, and metamaterials. This program will support a world-leading team in nanophotonics and metamaterials. It will introduce and demonstrate novel concepts for manipulating optical pulses in specially designed nanoscale structures, making an essential step towards the creation of all-optical devices which perform fast switching and processing of optical signals. These developments will underpin the next generation of high-performance networks promising to revolutionize global communications. This research program will keep Australia at the forefront of international research and provide training for students in breakthrough applications of photonics and nanotechnology, contributing to the uptake of frontier technologies by Australian industries.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100805
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Radioisotope-powered Parallel Electron Lithography for High-throughput Nano-manufacturing. This project aims to realise rapid fabrication of controllable nano-devices over large areas with high throughput and low cost. The lack of large-size (greater than four inch) mask and ultra-low dose resist are the fundamental challenges for high-throughput radioisotope-powered parallel electron nano-lithography (RIPEL) systems. This project aims to realise a large-size RIPEL mask by using the ultra-light ....Radioisotope-powered Parallel Electron Lithography for High-throughput Nano-manufacturing. This project aims to realise rapid fabrication of controllable nano-devices over large areas with high throughput and low cost. The lack of large-size (greater than four inch) mask and ultra-low dose resist are the fundamental challenges for high-throughput radioisotope-powered parallel electron nano-lithography (RIPEL) systems. This project aims to realise a large-size RIPEL mask by using the ultra-light supporting material aerographite that has a state-of-the-art ratio value of Young's modulus to cubic density. It will also develop a new inorganic nanoparticle resist with ultra-low dose. These building blocks will enhance RIPEL's throughput by four orders of magnitude. The project will contribute to making processors or solid state storage cheaper and more efficient.Read moreRead less