Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100062
Funder
Australian Research Council
Funding Amount
$700,000.00
Summary
Silicon LPCVD Facility for Nanoelectronics, Quantum Computing & Solar Cells. Silicon low-pressure chemical vapor deposition facility:
This project aims to complete Australia’s first manufacturing line for nanoscale devices. It aims to establish a low-pressure chemical vapour deposition system to complete the existing silicon complementary metal-oxide semiconductor process line. It is currently impossible to fabricate many devices compatible with industrial manufacture, limiting device reliabili ....Silicon LPCVD Facility for Nanoelectronics, Quantum Computing & Solar Cells. Silicon low-pressure chemical vapor deposition facility:
This project aims to complete Australia’s first manufacturing line for nanoscale devices. It aims to establish a low-pressure chemical vapour deposition system to complete the existing silicon complementary metal-oxide semiconductor process line. It is currently impossible to fabricate many devices compatible with industrial manufacture, limiting device reliability and path to commercialisation. The tool is designed to incorporate four furnace tubes for growing thin layers of electronic materials, including polycrystalline-silicon, epitaxial silicon, and silicon-nitride. One unique aspect will be growth of isotopically-enriched silicon-28 that is essential for spin-based quantum computing. The tool would support a wide range of projects nationally in silicon micro/nano-systems, advanced photovoltaics, and quantum technologies.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100159
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
National facility for biased target deposition of alloyed nanolayers. This facility will enhance Australia's strengths and capabilities in fabricating structures, with applications in multiple research fields including opto-magneto-electronics, next generation lithium ion batteries and energy nanogenerators. It will enhance Australia's research profile as a leader in nanotechnology.
Performance bottlenecks in ultra-scaled field-effect transistors. The comparison of commercial and atomically-precise devices will result in the long sought after atomistic metrology knowledge. Such knowledge is required to achieve a leap forward in device understanding and design in order to improve speed, reliability and energy consumption.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100001
Funder
Australian Research Council
Funding Amount
$410,000.00
Summary
Collaborative advanced spectroscopy facility for materials and devices. Collaborative advanced spectroscopy facility for materials and devices: This project aims to enable advancements in electronics, photonics, biomedicine, and sensing through a collaborative, open access facility for advanced optical and chemical spectroscopy of thin films, materials, and devices. The intended capabilities include high-speed, precise and state-of-the-art spectroscopy tools which enable in situ characterisation ....Collaborative advanced spectroscopy facility for materials and devices. Collaborative advanced spectroscopy facility for materials and devices: This project aims to enable advancements in electronics, photonics, biomedicine, and sensing through a collaborative, open access facility for advanced optical and chemical spectroscopy of thin films, materials, and devices. The intended capabilities include high-speed, precise and state-of-the-art spectroscopy tools which enable in situ characterisation at sub-micron scales and cryogenic temperatures, under bio-simulated environments, down to single pixel resolution, with parallel imaging and spectroscopy, and of fluids and biomaterials. The instrumentation will include cryogenic sub-micron photoluminescence and micro-Raman spectroscopy, single pixel optical and dark field spectroscopy, continuous wave terahertz time-domain spectroscopy, wide wavelength microscopic spectroscopy, and temperature-jump kinetics spectroscopy. It is expected that these complementary instruments will accelerate research in materials and devices for plasmonics, nanoelectronics, biomedicine, biochemistry, security, and forensic science.Read moreRead less
Nanostructured ferroic oxides: Why does defect-induced nanoscale heterogeneity matter? Ferroic oxides are an important class of functional materials used in applications such as storage memories, medical devices and smart sensors. This project will significantly impact the fundamental understanding and development of ferroic devices by revealing the underpinning interface mechanisms that govern their behaviour in nanostructured form.
Photonic chip inertial movement sensors. This project aims to create a new class of optical inertial movement sensors using integrated photonic chip technology. By replacing optical fibre coils with compact waveguides, integrating light sources on-chip and by harnessing smart sensing approaches, we intend to reduce the required power from watts to milliwatts and reduce the dimensions from meters to centimetres. The expected project outcomes are sensors with military grade precision but with the ....Photonic chip inertial movement sensors. This project aims to create a new class of optical inertial movement sensors using integrated photonic chip technology. By replacing optical fibre coils with compact waveguides, integrating light sources on-chip and by harnessing smart sensing approaches, we intend to reduce the required power from watts to milliwatts and reduce the dimensions from meters to centimetres. The expected project outcomes are sensors with military grade precision but with the size, cost and manufacturability of consumer electronics. This technology will fill a strategic gap in the movement sensor market enabling applications ranging from robotic infrastructure monitoring, manufacture and surgery to guiding satellites and other space craft.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100164
Funder
Australian Research Council
Funding Amount
$680,000.00
Summary
Dynamic phase behaviour characterisation facility for nanostructured interfaces and solids. This infrastructure will increase our understanding of interfacial phenomena of nanostructured materials over very short periods of time. This new understanding will allow optimisation of the correlation of the chemistry of a material to the properties of that material. The infrastructure will enhance Australia's capabilities in creating new materials relevant to electronics, medicine, the environment and ....Dynamic phase behaviour characterisation facility for nanostructured interfaces and solids. This infrastructure will increase our understanding of interfacial phenomena of nanostructured materials over very short periods of time. This new understanding will allow optimisation of the correlation of the chemistry of a material to the properties of that material. The infrastructure will enhance Australia's capabilities in creating new materials relevant to electronics, medicine, the environment and security technologies.Read moreRead less
Bioelectronic logic. This project aims to understand ion-electron interactions relevant to bioelectronics, and create transducing interfaces. Bioelectronics is a frontier field which aims to connect biological systems with modern electronics and so create biomedical devices. Transducing ion and electron signals using a biocompatible functional interface is difficult since ion and electron physics are different. By combining individual transducers, this project intends to demonstrate ground-break ....Bioelectronic logic. This project aims to understand ion-electron interactions relevant to bioelectronics, and create transducing interfaces. Bioelectronics is a frontier field which aims to connect biological systems with modern electronics and so create biomedical devices. Transducing ion and electron signals using a biocompatible functional interface is difficult since ion and electron physics are different. By combining individual transducers, this project intends to demonstrate ground-breaking bioelectronic logic capable of interface-level processing. The stretch goal is to test this new logic with a biological neuronal model. The project could deliver new science and interfacing elements to integrate tissue and circuitry, and demonstrate these in a real biological model.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
Industry Laureate Fellowships - Grant ID: IL230100072
Funder
Australian Research Council
Funding Amount
$3,759,824.00
Summary
Unleashing the combined power of electrons and holes for quantum computing. Large scale quantum computers promise unprecedented power with applications ranging from searching large databases for images and video, to optimising traffic routing, cryptography, and simulating advanced new materials and drug designs. This Fellowship will partner with Diraq, a world-leading Australian company developing a revolutionary new silicon quantum computing technology, to solve key issues in the race to scale ....Unleashing the combined power of electrons and holes for quantum computing. Large scale quantum computers promise unprecedented power with applications ranging from searching large databases for images and video, to optimising traffic routing, cryptography, and simulating advanced new materials and drug designs. This Fellowship will partner with Diraq, a world-leading Australian company developing a revolutionary new silicon quantum computing technology, to solve key issues in the race to scale from small scale prototypes to industrially relevant quantum computers. It will integrate electrons and holes, semiconducting and superconducting functionalities, into a single platform, link with industrial partners, and reinforce Australia's leadership position in quantum computing technologies.Read moreRead less