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Development of a light detection system for enhanced scanning electron microscopy imaging of fully hydrated biological specimens at room temperature. This project aims to develop instrumentation and techniques to image fully hydrated cellS for prolonged periods at room temperature in an environmental scanning electron microscope. Multiple fluorescent nano-particle labels will be used to image complex cellular structure and dynamics at ultra high spatial resolution. This innovative bio-imaging te ....Development of a light detection system for enhanced scanning electron microscopy imaging of fully hydrated biological specimens at room temperature. This project aims to develop instrumentation and techniques to image fully hydrated cellS for prolonged periods at room temperature in an environmental scanning electron microscope. Multiple fluorescent nano-particle labels will be used to image complex cellular structure and dynamics at ultra high spatial resolution. This innovative bio-imaging technique will be facilitated by the construction of a high speed light collection system that can efficiently operate at the pressures required to stablise water within the cell. Applications for this new bio-imaging technique will also be explored.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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560850
Funder
Australian Research Council
Funding Amount
$295,320.00
Summary
Scanning Cathodoluminescence Microscopy and Spectroscopy Facility. Cathodoluminescence (CL), the emission of light during electron irradiation, has emerged as a unique analytical tool to characterise luminescence centres and study luminescence mechanisms in technologically important materials at the nano-scale. The main aim of this project is to establish a state-of-the-art scanning CL microscopy and spectroscopy facility in Australia. The facility will enable high spatial resolution CL analysis ....Scanning Cathodoluminescence Microscopy and Spectroscopy Facility. Cathodoluminescence (CL), the emission of light during electron irradiation, has emerged as a unique analytical tool to characterise luminescence centres and study luminescence mechanisms in technologically important materials at the nano-scale. The main aim of this project is to establish a state-of-the-art scanning CL microscopy and spectroscopy facility in Australia. The facility will enable high spatial resolution CL analysis of technologically important semiconductors and novel nano-structured materials, e.g. quantum dots and ceramic nano-crystals. These studies will facilitate a deeper understanding of the physics of light emission from nano-structured materials and enable the fabrication of higher quality opto-electronic materials.Read moreRead less
Nanoparticle fluorescent labels as a platform for high throughput data gathering. Recent developments in genomics require gathering of vast amounts of information in a rapid and cost-effective fashion. To this aim we will develop a new fluorescent labelling technology with adequate throughput and high level of multiplexing. We will exploit recent advances in nanoparticle science combined with our own discoveries concerning rare earth ions as fluorescence activators. Our approach promises a combi ....Nanoparticle fluorescent labels as a platform for high throughput data gathering. Recent developments in genomics require gathering of vast amounts of information in a rapid and cost-effective fashion. To this aim we will develop a new fluorescent labelling technology with adequate throughput and high level of multiplexing. We will exploit recent advances in nanoparticle science combined with our own discoveries concerning rare earth ions as fluorescence activators. Our approach promises a combination of great technological simplicity, low fabrication costs, cutting edge performance and gives an additional time-resolved modality. Our fluorescent labels will be field-tested to search for yet unknown microorganisms.Read moreRead less
Analysis, Optimization, and Control of Scanning Atomic Force Microscope Micro-Cantilever Probes. Atomic Force Microscopes (AFM's) are widely used for the examination of samples smaller than can be observed with an optical microscope. A tiny 'finger', only a few atoms wide at its sharpest point, is used to 'feel' the surface of a sample. This project aims to increase the resolution of AFM images by actively controlling the sensor probe dynamics.
Better quality AFM images would allow scientists ....Analysis, Optimization, and Control of Scanning Atomic Force Microscope Micro-Cantilever Probes. Atomic Force Microscopes (AFM's) are widely used for the examination of samples smaller than can be observed with an optical microscope. A tiny 'finger', only a few atoms wide at its sharpest point, is used to 'feel' the surface of a sample. This project aims to increase the resolution of AFM images by actively controlling the sensor probe dynamics.
Better quality AFM images would allow scientists to further investigate the atomic and molecular structure of such samples as: metals, polymers, cells, and proteins.
This research will contribute to the design of an Australian made Scanning Probe Microscope. Development of local expertise will provide a valuable resource for Australian scientific and industrial research.
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Nano-optics and ultra-thin materials for an infrared spectrometer-on-a-chip. Aims: This project aims to advance optical nanoresonators and ultra-thin materials in the infrared spectral region. The project aims to use this knowledge to demonstrate an infrared spectrometer on a chip.
Significance: Infrared spectroscopy is a powerful method for identifying and study matter but is carried out using instruments that are generally large, heavy, power hungry and costly.
Expected outcomes: It is expec ....Nano-optics and ultra-thin materials for an infrared spectrometer-on-a-chip. Aims: This project aims to advance optical nanoresonators and ultra-thin materials in the infrared spectral region. The project aims to use this knowledge to demonstrate an infrared spectrometer on a chip.
Significance: Infrared spectroscopy is a powerful method for identifying and study matter but is carried out using instruments that are generally large, heavy, power hungry and costly.
Expected outcomes: It is expected that this project will generate knowledge that will allow dramatic reductions in the size, weight, power consumption and cost of infrared spectrometers.
Benefits: This should allow infrared spectrometers to be used in applications for which the size/weight/power consumption/cost of current approaches prevent their use.
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