Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100190
Funder
Australian Research Council
Funding Amount
$205,000.00
Summary
High through-put facility for measurement of quantum materials and devices. This projects aims to accelerate the development of quantum technologies by expanding our capacity to rapidly evaluate the low temperature electrical and optical properties of novel materials and devices. The project expects to generate new knowledge in quantum coherent phases of diamond, high mobility two-dimensional spintronics, hybrid semiconductor-superconductor devices, novel phases of silicon and germanium, and sin ....High through-put facility for measurement of quantum materials and devices. This projects aims to accelerate the development of quantum technologies by expanding our capacity to rapidly evaluate the low temperature electrical and optical properties of novel materials and devices. The project expects to generate new knowledge in quantum coherent phases of diamond, high mobility two-dimensional spintronics, hybrid semiconductor-superconductor devices, novel phases of silicon and germanium, and single photon sources based on silicon-carbide. Expected outcomes of the project include the establishment of high performing, efficient, new facilities for low temperature quantum measurement, the strengthening of collaborative links between participating researchers and the expansion of opportunities for research students.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100839
Funder
Australian Research Council
Funding Amount
$442,162.00
Summary
Nanoarchitectured platform technology for molecular profiling of exosomes. The aim of this project is to develop a set of cutting-edge nanotechnologies and a nanofabrication strategy to create a highly sensitive platform technology for exosome and exosomal miRNA analysis. This project aims to generate new knowledge in mesoporus nanomaterials and transudcer as well as exosome chemistry by developing nanostructure-based platform technology (device) for automated and rapid analysis. This project's ....Nanoarchitectured platform technology for molecular profiling of exosomes. The aim of this project is to develop a set of cutting-edge nanotechnologies and a nanofabrication strategy to create a highly sensitive platform technology for exosome and exosomal miRNA analysis. This project aims to generate new knowledge in mesoporus nanomaterials and transudcer as well as exosome chemistry by developing nanostructure-based platform technology (device) for automated and rapid analysis. This project's findings are expected to provide Australia with cutting-edge expertise for developing a next-generation platform technology for analysing exosomes and other relevant biomolecules, with the potential to deliver valuable intellectual property of commercial interest and economic benefit through technological advancements.Read moreRead less
Scalable nanomechanical information processing. This project aims to build the first scalable computer architecture based on nanoscale motion on a silicon chip. Such nanomechanical computers could extend computing performance in space and earth-orbit applications, and in other environments where intense radiation causes digital electronics to fail. The project intends to utilise recent advances in nanomechanics and nanofabrication to demonstrate all key nanomechanical circuit elements, including ....Scalable nanomechanical information processing. This project aims to build the first scalable computer architecture based on nanoscale motion on a silicon chip. Such nanomechanical computers could extend computing performance in space and earth-orbit applications, and in other environments where intense radiation causes digital electronics to fail. The project intends to utilise recent advances in nanomechanics and nanofabrication to demonstrate all key nanomechanical circuit elements, including transistors, logic gates, memories and analogue-to-digital converters and to deliver a roadmap for commercialisation of the technology in Australia. The expected outcome of this project is the development of the underpinning nanotechnologies, predicted to have wide uses in sensing, health and communications,and which could improve heat management and energy efficiency in future computers. This new approach to computing has potential for near-term commercial impact in the aerospace industry, building on Australian know-how.Read moreRead less
Surface doping of diamond: A new platform for 2D carbon-based spintronics. This project aims to develop the hydrogen-terminated surface of diamond as a new semiconducting platform for carbon-based spintronics. It will build upon recent experimental advances that have shown diamond to possess a two-dimensional (2D) hole-based system with strong spin-orbit coupling. As a semiconductor with unique spin properties, surface conducting diamond offers considerable advantages over other 2D materials su ....Surface doping of diamond: A new platform for 2D carbon-based spintronics. This project aims to develop the hydrogen-terminated surface of diamond as a new semiconducting platform for carbon-based spintronics. It will build upon recent experimental advances that have shown diamond to possess a two-dimensional (2D) hole-based system with strong spin-orbit coupling. As a semiconductor with unique spin properties, surface conducting diamond offers considerable advantages over other 2D materials such as graphene and topological insulators. These unique properties will be exploited to realise novel semiconductor device architectures for the manipulation of spin using electric fields, and for the study of new spin transport phenomena and quasiparticle excitations at semiconductor-superconductor interfaces.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100124
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Rapid prototyping 3-D nano-pattern large area writer . Rapid prototyping 3-D nano-pattern large area writer:
The project aims to establish a nanoscale three-dimensional patterning rapid prototyping capability to enable advanced nanofabrication research and development. The extension of patterning nanostructured materials in three dimensions with nanometre resolution, developed for semiconductor processing, to nano-electronics, nanophotonics, nanosensors, nanobiotechnology and fundamental studi ....Rapid prototyping 3-D nano-pattern large area writer . Rapid prototyping 3-D nano-pattern large area writer:
The project aims to establish a nanoscale three-dimensional patterning rapid prototyping capability to enable advanced nanofabrication research and development. The extension of patterning nanostructured materials in three dimensions with nanometre resolution, developed for semiconductor processing, to nano-electronics, nanophotonics, nanosensors, nanobiotechnology and fundamental studies of nanoscale phenomena in science and engineering has opened new opportunities in these areas. As these areas accelerate, there is a need to develop nanoscale patterns and structures via rapid prototyping pathways and with methods accessible to an ever-diverse researcher base without a background in nanofabrication. By establishing the first NanoFrazor in Australia, this project aims to provide new technology for the fabrication of high-resolution nanoscale structures and patterns.
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Swift heavy ion induced nano-porous antimony-based semiconductors. This project aims to study the fabrication and application of nano-porous antimony based semiconductors prepared by high-energy ion irradiation. Using a unique combination of synchrotron and laboratory- based analytical techniques as well as computer simulations, the project expects to identify the physical mechanisms for porous structure formation and exploit the materials for application in thermoelectric and thermo-photovoltai ....Swift heavy ion induced nano-porous antimony-based semiconductors. This project aims to study the fabrication and application of nano-porous antimony based semiconductors prepared by high-energy ion irradiation. Using a unique combination of synchrotron and laboratory- based analytical techniques as well as computer simulations, the project expects to identify the physical mechanisms for porous structure formation and exploit the materials for application in thermoelectric and thermo-photovoltaic devices. Expected outcomes of the project include fabrication processes compatible with current device fabrication methodologies that should enable rapid integration of the materials into advanced device applications. Significant benefits should result from novel applications of the technologies such as energy harvesting and sensor devices.Read moreRead less
Scalable atom-thin materials for monolithic electronics & optoelectronics. This project aims to understand large-area growth mechanisms and create practical, controllable doping methodologies for developing manufacturing-compatible tunable materials to overcome technological challenges presented by silicon. The project expects to generate new understanding of physico-chemical mechanisms that govern the optical and electrical properties of an emerging class of materials only few-atoms thick that ....Scalable atom-thin materials for monolithic electronics & optoelectronics. This project aims to understand large-area growth mechanisms and create practical, controllable doping methodologies for developing manufacturing-compatible tunable materials to overcome technological challenges presented by silicon. The project expects to generate new understanding of physico-chemical mechanisms that govern the optical and electrical properties of an emerging class of materials only few-atoms thick that offer unprecedented opportunities. This is expected to establish a suite of atomically-thin materials that will be deployed in miniaturised, high-density electronics and optoelectronics of which proof-of-concept functional devices are proposed to be demonstrated. These will be leveraged to explore industry partnerships.Read moreRead less
Room Temperature Quantum Devices based on Spins in Organic Semiconductors:
Characterisation, Control and Development. Organic semiconductors are widely used in optoelectronic devices - recent work has also demonstrated that they contain coherent quantum spin states, even at room temperature. This project will use spin resonance and control techniques from quantum physics to determine the processes which limit coherence in these materials, determine ways to overcome these limitations, and then i ....Room Temperature Quantum Devices based on Spins in Organic Semiconductors:
Characterisation, Control and Development. Organic semiconductors are widely used in optoelectronic devices - recent work has also demonstrated that they contain coherent quantum spin states, even at room temperature. This project will use spin resonance and control techniques from quantum physics to determine the processes which limit coherence in these materials, determine ways to overcome these limitations, and then incorporate the materials into devices which exploit the power of these quantum systems at room-temperature. This project advances the prospect of ubiquitously incorporating quantum technologies into everyday applications, impacting fields from information storage to sensing.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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100170
Funder
Australian Research Council
Funding Amount
$560,000.00
Summary
Ultra low temperature scanning gate facility for study of advanced nanostructure devices and materials. Ultra low temperature scanning gate facility for study of advanced nanostructure devices and materials: Electronic devices and materials underpin a range of significant industries worldwide. However while there are numerous techniques for imaging the structure of a material, including X-rays, electron microscopy, atom probe tomography, and nuclear scattering, none allow us to see how the elect ....Ultra low temperature scanning gate facility for study of advanced nanostructure devices and materials. Ultra low temperature scanning gate facility for study of advanced nanostructure devices and materials: Electronic devices and materials underpin a range of significant industries worldwide. However while there are numerous techniques for imaging the structure of a material, including X-rays, electron microscopy, atom probe tomography, and nuclear scattering, none allow us to see how the electrons and holes move inside a material or device. This project will create a new scanning gate microscope facility for imaging electrical current flow in advanced quantum devices and the new generation of topological insulators and atomically thin crystals such as graphene. The project will stimulate new studies of the next generation of electronic materials and devices, providing the underpinning knowledge for the future development of post silicon electronics.Read moreRead less