Disposable microdevices for fast ion analysis. The design and fabrication of a microdevice for ion chromatography will introduce Australia to the field of miniaturised total analytical systems (µTAS). The availability of infrastructure, technology and experience in the µTAS area will provide the foundation for specialised commercialisation of sophisticated, chip-based analytical instruments. These instruments have important applications in forensic, clinical and environmental chemistry.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347937
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Imaging Raman Spectrometer. An Imaging Raman spectrometer generates image maps 10x faster than older instruments and is required to meet escalating demand. This results from innovative use of Raman to characterise organics, polymers, thin films and biomaterials, which underpins rapidly evolving research in nanotechnology and biotechnology. Many innovations have come from QUT's Centre for Instrumental and Developmental Chemistry, which will host the spectrometer and is a key resource for all Qu ....Imaging Raman Spectrometer. An Imaging Raman spectrometer generates image maps 10x faster than older instruments and is required to meet escalating demand. This results from innovative use of Raman to characterise organics, polymers, thin films and biomaterials, which underpins rapidly evolving research in nanotechnology and biotechnology. Many innovations have come from QUT's Centre for Instrumental and Developmental Chemistry, which will host the spectrometer and is a key resource for all Queensland universities. The availability of its high quality spectroscopic facility has enabled leading edge developments by local companies and the Imaging Raman spectrometer will significantly accelerate and enhance current and future project outcomes.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560818
Funder
Australian Research Council
Funding Amount
$154,000.00
Summary
A Pico-Newton Scale Force Measurement Apparatus for Polymer Physics and Non-equilibrium Statistical Mechanics. We propose to build a state-of-the-art Optical Tweezers apparatus that measures small forces and torques on micron-sized objects located in 'optical traps'. Using a single laser beam and computer-generated holograms, we will create arrays of optical traps that move or 'dance', and alter the force/torque-imposing properties of each trap. This proposed research equipment will be used (1 ....A Pico-Newton Scale Force Measurement Apparatus for Polymer Physics and Non-equilibrium Statistical Mechanics. We propose to build a state-of-the-art Optical Tweezers apparatus that measures small forces and torques on micron-sized objects located in 'optical traps'. Using a single laser beam and computer-generated holograms, we will create arrays of optical traps that move or 'dance', and alter the force/torque-imposing properties of each trap. This proposed research equipment will be used (1) to study the physics of single synthetic polymer and naturally occuring biopolymer chains, (2) to quantify experimentally, and for the first time, newly predicted molecular-scale forces, and (3) to demonstrate new theories in non-equilibrium statistical mechanics that quantitatively describe the operation of nanomachines. Read moreRead less
Light-Matter Interactions In Nanoparticle-doped Microstructured Polymer Fibres. Microstructured optical fibres have been defined as the 'next generation' of optical fibres. This proposal offers the opportunity to make major advances in this dynamic new area, not only changing the fibre properties by means of its microstructured but also by its material properties. The proposed research will enable us to fabricate new types of optical fibre by exploiting three completely different technologies: p ....Light-Matter Interactions In Nanoparticle-doped Microstructured Polymer Fibres. Microstructured optical fibres have been defined as the 'next generation' of optical fibres. This proposal offers the opportunity to make major advances in this dynamic new area, not only changing the fibre properties by means of its microstructured but also by its material properties. The proposed research will enable us to fabricate new types of optical fibre by exploiting three completely different technologies: polymer materials, microstructured polymer fibres (mPOF) and nanoparticles. This project will build on our existing success in developing mPOF, and create major new opportunities, both in fundamental science and in applications that could and would be commercialised.Read moreRead less
Modifying and Improving Porous Sol-Gel Materials for Water Purification. XeroCoat is commercialising nanotechnology research out of UQ's Physics department. XeroCoat has received much local and international interest in its signature product 'XeroCoat'. The company is rapidly expanding and has established new research facilities with production facilities to be set-up. This will result in high technology, employment growth for Australia. Links with Flinders could see expansion into SA. The c ....Modifying and Improving Porous Sol-Gel Materials for Water Purification. XeroCoat is commercialising nanotechnology research out of UQ's Physics department. XeroCoat has received much local and international interest in its signature product 'XeroCoat'. The company is rapidly expanding and has established new research facilities with production facilities to be set-up. This will result in high technology, employment growth for Australia. Links with Flinders could see expansion into SA. The company operates in 'Sol-Gel' nanotechnology, which has huge global, academic and commercial interest. However in Australia this technology has only been serviced by Flinders, ANSTO and ANSTO's spin-out company Ceramisphere. The project will help to build a new Australian high tech industry in sol-gel nanotechnology.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0561157
Funder
Australian Research Council
Funding Amount
$110,000.00
Summary
Multi-functional fluorescence microscopy laboratory. We have proposed a multipurpose fluorescent microscopy facility coupled to the RMIT microfabrication facility primarily for the study of the processes that make up lab-on-a-chip systems (the miniaturisation of a laboratory full of equipment to fit onto a credit card sized chip). Specifically the heart of the equipment, the variable wavelength pulsed laser coupled to an inverted microscope, will allow the study of temperature and fluid flow i ....Multi-functional fluorescence microscopy laboratory. We have proposed a multipurpose fluorescent microscopy facility coupled to the RMIT microfabrication facility primarily for the study of the processes that make up lab-on-a-chip systems (the miniaturisation of a laboratory full of equipment to fit onto a credit card sized chip). Specifically the heart of the equipment, the variable wavelength pulsed laser coupled to an inverted microscope, will allow the study of temperature and fluid flow in microchannels, the development of new electro-optic components, direct visualisation of electromagnetic radiation and its effect on cells, and the coupling of electrical and optical stimulation and sensing devices to microfluidic channels. Read moreRead less