Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100090
Funder
Australian Research Council
Funding Amount
$1,136,244.00
Summary
Xe-plasma dual beam for advanced future materials. This project aims to establish a state of the art Xe-Plasma dual-beam facility providing characterisation and fabrication capabilities to Australia’s research community. The project will use two beams - one Xe, the other electrons - to mill the surface of bulk materials which are subsequently analysed by electron or ion beam techniques to determine atomic-scale microstructure(s) and compositions. Anticipated outcomes are advanced materials engin ....Xe-plasma dual beam for advanced future materials. This project aims to establish a state of the art Xe-Plasma dual-beam facility providing characterisation and fabrication capabilities to Australia’s research community. The project will use two beams - one Xe, the other electrons - to mill the surface of bulk materials which are subsequently analysed by electron or ion beam techniques to determine atomic-scale microstructure(s) and compositions. Anticipated outcomes are advanced materials engineering and new knowledge about ancient and future materials. This is expected to provide significant advances across a variety of fields including material science, engineering and geology and enhance trans-disciplinary collaborations.Read moreRead less
Enhanced sensitivity of electrospray ionization mass spectrometry. Enhanced sensitivity of electrospray ionization mass spectrometry. This project aims to enhance the sensitivity of nano-electrospray ionization mass spectrometry (nanoESI-MS) by an order of magnitude by simultaneously overcoming the two interdependent limitations in ion generation and transmission efficiency. This project will design glass capillaries and tubes with complex structures to enable both multiplexing ion generation fr ....Enhanced sensitivity of electrospray ionization mass spectrometry. Enhanced sensitivity of electrospray ionization mass spectrometry. This project aims to enhance the sensitivity of nano-electrospray ionization mass spectrometry (nanoESI-MS) by an order of magnitude by simultaneously overcoming the two interdependent limitations in ion generation and transmission efficiency. This project will design glass capillaries and tubes with complex structures to enable both multiplexing ion generation from a single capillary and geometrically matching the bore of the tube collecting the emitted ion plume. NanoESI-MS has become an indispensable analytical tool for proteomics and synthetic chemistry. The significant enhancement of nanoESI-MS sensitivity in this project is expected to accelerate progress in disease research, biomarker discovery and drug development.Read moreRead less
Exploring the Dynamics of Nanostructure Self-Organisation during Compound Semiconductor Epitaxy. The application of LEEM to GaAs and InAs will be a world first, positioning Australia at the forefront of nanoscale self-organisation, leading to important international recognition and publicity. The spectacular movies obtained will revolutionise our basic understanding of compound semiconductor self-organisation and facilitate an improved control over nanostructure fabrication using MBE. This will ....Exploring the Dynamics of Nanostructure Self-Organisation during Compound Semiconductor Epitaxy. The application of LEEM to GaAs and InAs will be a world first, positioning Australia at the forefront of nanoscale self-organisation, leading to important international recognition and publicity. The spectacular movies obtained will revolutionise our basic understanding of compound semiconductor self-organisation and facilitate an improved control over nanostructure fabrication using MBE. This will generate entirely new device structures relevant to the frontier technologies of photonics and quantum information processing. The project will provide high level training for post-graduate and honours students in nanoscale characterisation and synchrotron science.Read moreRead less
Diamond Microneedles for Minimally Invasive Blood Collection. Blood sampling is a routine procedure for medical purposes to determine the physiological and biochemical status of patients. The aim of this project is to develop a reliable microneedle array for a blood collection procedures. Micro-scale needles for low-volume perforated blood samples are highly desirable due to its minimal invasiveness and painlessness. The miniaturization of sampling platforms driven by microneedles has the poten ....Diamond Microneedles for Minimally Invasive Blood Collection. Blood sampling is a routine procedure for medical purposes to determine the physiological and biochemical status of patients. The aim of this project is to develop a reliable microneedle array for a blood collection procedures. Micro-scale needles for low-volume perforated blood samples are highly desirable due to its minimal invasiveness and painlessness. The miniaturization of sampling platforms driven by microneedles has the potential to shift disease diagnosis and monitoring closer to the point of care. Expected outcomes include the development of synthetic diamond-based microneedles for the potential to greatly benefit society through improved and affordable healthcare and the development of new high-tech industries.Read moreRead less
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
Real-time imaging of crystal strengthening mechanisms in metals. The strength limit of a metal is marked by rapid motion of crystalline defects. The associated speeds can locally approach that of sound. To probe the associated mechanisms clearly requires both spatial and temporal resolution. We propose to create a new bulk x-ray technique with an unprecedented combination of temporal and spatial resolution. We plan to exploit the technique to mediate a step change in modelling strength based on ....Real-time imaging of crystal strengthening mechanisms in metals. The strength limit of a metal is marked by rapid motion of crystalline defects. The associated speeds can locally approach that of sound. To probe the associated mechanisms clearly requires both spatial and temporal resolution. We propose to create a new bulk x-ray technique with an unprecedented combination of temporal and spatial resolution. We plan to exploit the technique to mediate a step change in modelling strength based on twinning. The formation of crystalline twins is known to dictate the strength of the light metal magnesium. A fuller understanding of the effect of twinning on strength in this metal will provide much needed confidence to implement it more widely in energy saving applications.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0239650
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Advanced instrumentation for nano-scale imaging and analysis. It is widely accepted that the emerging fields of Nanotechnology and Nanoengineering will dominate research activity in a wide range of disciplines over the next decade. Progress in nanoscience and technology requires parallel development in nanocharacterisation and nanofabrication techniques. This proposal seeks to enhance the level of research infrastructure support for nano-scale microscopy and microanalysis at UTS and the Univer ....Advanced instrumentation for nano-scale imaging and analysis. It is widely accepted that the emerging fields of Nanotechnology and Nanoengineering will dominate research activity in a wide range of disciplines over the next decade. Progress in nanoscience and technology requires parallel development in nanocharacterisation and nanofabrication techniques. This proposal seeks to enhance the level of research infrastructure support for nano-scale microscopy and microanalysis at UTS and the University of Sydney by providing the following advanced instrumentation for nano-scale imaging, analysis and manipulation of materials:
- A Schottky field emission gun environmental scanning electron microscope
- Equipment kit for the rapid preparation of high quality transmission electron microscope specimens.Read moreRead less
Synthesis and Optimisation of Ultra-Thin Metal Oxide Coatings. Metal oxides are a rich class of materials in terms of their electronic, optical and chemical properties. The emergence of nanotechnology has renewed the drive for miniaturisation and given new urgency to the synthesis of ultra-thin metal oxide films for use in new electronic devices, sensors and functional coatings. This project will generate valuable intellectual property in the form of optimised ultra-thin metal oxide coatings wit ....Synthesis and Optimisation of Ultra-Thin Metal Oxide Coatings. Metal oxides are a rich class of materials in terms of their electronic, optical and chemical properties. The emergence of nanotechnology has renewed the drive for miniaturisation and given new urgency to the synthesis of ultra-thin metal oxide films for use in new electronic devices, sensors and functional coatings. This project will generate valuable intellectual property in the form of optimised ultra-thin metal oxide coatings with properties tailored to meet this rapidly growing set of new applications. The innovative combination of advanced plasma synthesis, high resolution microscopy and accurate theoretical modelling will ensure success. Read moreRead less
Magnetic liquid marbles: a new droplet manipulation technique for channel-free microfluidics. The project will explore the feasibility of developing a new droplet-manipulation strategy by using magnetically responsive liquid marbles capable of hosting various liquid droplets. It will significantly advance the development of a new generation of microfluidic devices: magnetic field-actuated channel-free droplet microfluidics.
Diamond glass: An all-carbon technology for neural networks and biosensing. This project aims to use plasma deposition to synthesise diamond glass with the highest purity and the most diamond-like character so that it meets the strict requirements for emerging device applications. The extreme properties of diamond glass arise from the diamond-like bonding of the majority of its atoms. This amorphous, wide bandgap semiconductor is also the hardest known glass. The maximum diamond-like content pos ....Diamond glass: An all-carbon technology for neural networks and biosensing. This project aims to use plasma deposition to synthesise diamond glass with the highest purity and the most diamond-like character so that it meets the strict requirements for emerging device applications. The extreme properties of diamond glass arise from the diamond-like bonding of the majority of its atoms. This amorphous, wide bandgap semiconductor is also the hardest known glass. The maximum diamond-like content possible in diamond glass coatings is unknown, so determining its ultimate performance is difficult. Expected applications include medical diagnostics, non-volatile memories and programmable chips.Read moreRead less