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
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
Ion implantation engineered photonic devices for use in highly integrated silicon optoelectronic circuits. This project establishes a collaboration with Canada's leading integrated silicon photonics research group thus tapping into years of valuable experience transferable to Australian-based researchers. The involvement of students as well as early career researchers ensures a new generation of Australian experts in this field. The importance of silicon photonics means that Australia must estab ....Ion implantation engineered photonic devices for use in highly integrated silicon optoelectronic circuits. This project establishes a collaboration with Canada's leading integrated silicon photonics research group thus tapping into years of valuable experience transferable to Australian-based researchers. The involvement of students as well as early career researchers ensures a new generation of Australian experts in this field. The importance of silicon photonics means that Australia must establish a strong research program in the area to maintain its current position as being at the forefront of leading-edge research. This is only possible through collaborations such as that proposed here.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347464
Funder
Australian Research Council
Funding Amount
$100,000.00
Summary
Setting up an integrated wirebonding and testing facility for MEMS applications. This project intends to setup an integrated wire bonding and testing facility suitable for Micro electromechanical systems (MEMS) applications. Wire bonding is an essential step for making the contacts of any micro device with external power supply or signal conditioning circuitry. The contact pads for such devices vary in size from 0.050 mm x 0.050 mm to few 100s of micrometers. The proposed facility will be requi ....Setting up an integrated wirebonding and testing facility for MEMS applications. This project intends to setup an integrated wire bonding and testing facility suitable for Micro electromechanical systems (MEMS) applications. Wire bonding is an essential step for making the contacts of any micro device with external power supply or signal conditioning circuitry. The contact pads for such devices vary in size from 0.050 mm x 0.050 mm to few 100s of micrometers. The proposed facility will be required for making contacts either using thermal or ultrasonic methods with complete automatic stages. The electrical contacts are used to drive or monitor MEMS, Polymer micro devices and nano- fluidic systems. This facility will be used for different applications including photonics and communication devices (RMIT), flexi circuits and microwave devices (DSTO) and micro/nano fluidic systems (SUT). This will be the only advanced integrated facility in Victoria, which will have the wire bonding(ball & wedge), die bonding and bond testing facilities together.Read moreRead less
Monolithic Integration of Silicon Waveguide and Ge1-xSix Photodetector on Silicon-on Insulator Platform for Intra-chip Optical Interconnect. Photonics has become the major technology underpinning the communication and storage of data. As photonics advances applications are emerging which demand components be manufactured cheaply in the manner achieved by the electronics industry in the silicon chip. Silicon is now emerging as an important photonic material and devices can benefit from inexpensiv ....Monolithic Integration of Silicon Waveguide and Ge1-xSix Photodetector on Silicon-on Insulator Platform for Intra-chip Optical Interconnect. Photonics has become the major technology underpinning the communication and storage of data. As photonics advances applications are emerging which demand components be manufactured cheaply in the manner achieved by the electronics industry in the silicon chip. Silicon is now emerging as an important photonic material and devices can benefit from inexpensive processing methods developed for electronics. This project aims to capture key intellectual property for monolithically integrating key photonic components onto a silicon platform. The project can bring social and commercial benefits to Australia such as high-level research and training in nanotechnology as well as opportunities for commercialisation in niche markets.Read moreRead less
Creation of novel photonic and nanostructured materials by ablation of solids with ultra-fast lasers. This project will study of the production of technologically important thin film materials and nanostructured materials using our patented ultra-fast pulsed laser deposition process. Thin film materials required for future applications in photonics will be a priority. In addition ultra-fast pulsed laser deposition can be used to create nanopartilces and mechanisms affecting the growth of these ....Creation of novel photonic and nanostructured materials by ablation of solids with ultra-fast lasers. This project will study of the production of technologically important thin film materials and nanostructured materials using our patented ultra-fast pulsed laser deposition process. Thin film materials required for future applications in photonics will be a priority. In addition ultra-fast pulsed laser deposition can be used to create nanopartilces and mechanisms affecting the growth of these materials will be studied. The project therefore falls into two priority areas: photon science and nanotechnology. Outcomes in addition to new knowledge will include materials and processes with commercial potential.Read moreRead less