New quantitative methods in X-ray imaging using crystal optics. This project will enhance Australian science's international leadership in the area of x-ray imaging. This powerful type of X-ray imaging, which makes use of optical elements made of perfect crystals, is specially tailored to image samples which are invisible to conventional x-ray techniques. Such "extended x-ray vision" is extremely important for imaging in medicine, biology and materials science. Furthermore, we will train x-ray s ....New quantitative methods in X-ray imaging using crystal optics. This project will enhance Australian science's international leadership in the area of x-ray imaging. This powerful type of X-ray imaging, which makes use of optical elements made of perfect crystals, is specially tailored to image samples which are invisible to conventional x-ray techniques. Such "extended x-ray vision" is extremely important for imaging in medicine, biology and materials science. Furthermore, we will train x-ray scientists of tomorrow, whose expertise will allow Australia to capitalize on its investment in the Australian Synchrotron.Read moreRead less
Development of a Novel and Quantitative Approach to Phase Imaging with Applications to Functional Nanomaterials. This project will improve and apply an innovative approach to obtaining phase information from electron microscopy images, currently being commercialised by IATIA Ltd. We will develop the approach so that it is fully quantitative, even at the nanoscale, and explore the effect of experimental parameters such as beam coherence, aberrations, specimen contamination and diffraction. We wil ....Development of a Novel and Quantitative Approach to Phase Imaging with Applications to Functional Nanomaterials. This project will improve and apply an innovative approach to obtaining phase information from electron microscopy images, currently being commercialised by IATIA Ltd. We will develop the approach so that it is fully quantitative, even at the nanoscale, and explore the effect of experimental parameters such as beam coherence, aberrations, specimen contamination and diffraction. We will apply the method to both physical and molecular nanomaterials, including a new class of self-organising molecules. Phase imaging can visualise the structures, polarities, charge and conductivity distributions in these materials and so assist in the development of new materials and devices.Read moreRead less
Scaling-up microstructured fibres for terahertz radiation. Terahertz radiation is the last region of the electromagnetic spectrum to be fully utilised. Many applications have been identified but their practicality has been limited by a lack of low-loss flexible waveguides. The waveguides to be developed in this project will build on Australia's existing international lead and investments in photonics as well as extend the dynamic field of microstructured optical fibres, indentified as the 'futur ....Scaling-up microstructured fibres for terahertz radiation. Terahertz radiation is the last region of the electromagnetic spectrum to be fully utilised. Many applications have been identified but their practicality has been limited by a lack of low-loss flexible waveguides. The waveguides to be developed in this project will build on Australia's existing international lead and investments in photonics as well as extend the dynamic field of microstructured optical fibres, indentified as the 'future' of optical fibres. Low-loss flexible waveguides will enable imaging and spectroscopy applications that can reveal and object's internal structure and composition. This will have immediate applications in security, quality control, medical imaging and other safety or industrial applications.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
Super-resolution in microscopy and optical recording. The classical resolution limit imposes severe restrictions on the performance of optical instruments, especially in optical microscopy and optical recording. Improved understanding of the fundamental principles involved in super-resolution should allow substantial increases in resolution to be achieved. We aim to explore theoretically and experimentally the performance of different super-resolution schemes alone and in combination, including ....Super-resolution in microscopy and optical recording. The classical resolution limit imposes severe restrictions on the performance of optical instruments, especially in optical microscopy and optical recording. Improved understanding of the fundamental principles involved in super-resolution should allow substantial increases in resolution to be achieved. We aim to explore theoretically and experimentally the performance of different super-resolution schemes alone and in combination, including optical masks, near-field optics, detector arrays, multi-photon imaging and digital deconvolution. Selected methods will be demonstrated with practical examples in multi-photon microscopy. Applications in super-high density optical recording will also be studied.Read moreRead less
Scanning Probe Microscopy for Fabrication and Analysis of Polymer Photovoltaics. Australian economic growth will depend increasingly on the provision of devices using materials designed at the molecular level. Scanning probe microscopy, which uses tips placed very close to surfaces to analyse or modify the surfaces with molecular precision, is an indispensible tool in designing such materials. In this project, scanning probe microscopy will be used to analyse and build structures on polymer sola ....Scanning Probe Microscopy for Fabrication and Analysis of Polymer Photovoltaics. Australian economic growth will depend increasingly on the provision of devices using materials designed at the molecular level. Scanning probe microscopy, which uses tips placed very close to surfaces to analyse or modify the surfaces with molecular precision, is an indispensible tool in designing such materials. In this project, scanning probe microscopy will be used to analyse and build structures on polymer solar cells in order to maximise the efficiency of the cells and build prototype nanoscale polymer devices. This will lead to the improvement in devices delivering sustainable energy production - a technology which has the promise of producing energy cheaply from sunlight.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347462
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Femtosecond laser micromachining facility. The proposed establishment of a femtosecond laser micromachining facility, with microdiagnostic capabilities, will facilitate a range of projects involving fabrication of submicron structures in metals, polymers, glasses, ceramics and crystalline materials. This facility, unique in Australia , will be comparable to the best such facilities in the world, enabling researchers to apply new microfabrication techniques to a range of photonic and optoelectro ....Femtosecond laser micromachining facility. The proposed establishment of a femtosecond laser micromachining facility, with microdiagnostic capabilities, will facilitate a range of projects involving fabrication of submicron structures in metals, polymers, glasses, ceramics and crystalline materials. This facility, unique in Australia , will be comparable to the best such facilities in the world, enabling researchers to apply new microfabrication techniques to a range of photonic and optoelectronic devices, including laser-written optical planar waveguides, nonlinear components and photonic bandgap structures , and various biomedical microstructures. Outcomes will include demonstration and development of novel photonic/optoelectronic devices and of new techniques, crucial to cost-effective manufacture of photonic components.Read moreRead less
Narrowband coherent light sources for spectroscopic sensing. The project will develop optical instruments and sensing techniques based on novel high-performance tunable optical parametric oscillator devices. These laser-like devices will be designed to monitor gases in a highly sensitive, molecule-specific way and thus indicate the presence and concentration of particular species with characteristic spectroscopic signatures. Useful applications will include optical sensing in science, industry ....Narrowband coherent light sources for spectroscopic sensing. The project will develop optical instruments and sensing techniques based on novel high-performance tunable optical parametric oscillator devices. These laser-like devices will be designed to monitor gases in a highly sensitive, molecule-specific way and thus indicate the presence and concentration of particular species with characteristic spectroscopic signatures. Useful applications will include optical sensing in science, industry, medicine, agriculture, community security, and the environment. In addition to making significant scientific discoveries and technological advances, the project will provide training for postgraduate research students and will develop intellectual property that may be of commercial benefit.Read moreRead less
Optical supercontinuum generation from high pulse-energy optical sources. The aim of this project is to develop a broadband and high brightness optical fibre source based on optical supercontinuum generation (i.e. low-coherence optical signals with octave or more bandwidth). Unlike similar sources demonstrated recently which rely on expensive bulk femtosecond pump lasers, this source will be pumped by a large pulse-energy optical fibre laser and use stimulated Raman scattering to seed the contin ....Optical supercontinuum generation from high pulse-energy optical sources. The aim of this project is to develop a broadband and high brightness optical fibre source based on optical supercontinuum generation (i.e. low-coherence optical signals with octave or more bandwidth). Unlike similar sources demonstrated recently which rely on expensive bulk femtosecond pump lasers, this source will be pumped by a large pulse-energy optical fibre laser and use stimulated Raman scattering to seed the continuum generation. The primary outcome will be a compact low-cost all-fibre supercontinuum source with a wide range of applications in areas such as optical metrology, optical coherence tomography, and high resolution non-contact position and motion sensing.Read moreRead less
Ringed photonic crystal fibres for broadband nonlinear optics. The technology developed from this project will enable organic molecules to be detected, identified and quantified. Because the technology is compact, easily engineered and low cost, it will lead to a dramatically increased capability for infrared spectroscopic measurement throughout biology and medicine, with specific benefits in agriculture, the food industry and defence.