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
Compact Low-Cost Tunable UV Lasers for Biosensing Applications. Detection and characterisation of micro-organisms such as airborne biological agents, parasites in domestic water supplies and micro-organisms used in the food and beverage industry, is of national importance. All biological systems have rich absorption signatures in the UV enabling detection of biological specimens with high sensitivity and selectivity using optical methods. For these applications compact and inexpensive tunable U ....Compact Low-Cost Tunable UV Lasers for Biosensing Applications. Detection and characterisation of micro-organisms such as airborne biological agents, parasites in domestic water supplies and micro-organisms used in the food and beverage industry, is of national importance. All biological systems have rich absorption signatures in the UV enabling detection of biological specimens with high sensitivity and selectivity using optical methods. For these applications compact and inexpensive tunable UV lasers are required; however to date tunable UV lasers have been limited to bulky and expensive systems. We propose to engineer novel, low cost, compact, tunable UV cerium lasers and demonstrate their applicability to selective optical detection of micro-organisms.Read moreRead less
Coherent LIDAR for Monitoring Air Pollution and Atmospheric Wind-fields. Industry, government and civil defence urgently require compact, field deployable sensors that can measure winds and monitor pollution in the atmospheric boundary layer. Without these sensors they are unable to measure and make informed decisions about windborne dispersion of industrial emissions, environmental pollutants, and chemical/biological toxins under operational conditions. The project will develop eye-safe cohere ....Coherent LIDAR for Monitoring Air Pollution and Atmospheric Wind-fields. Industry, government and civil defence urgently require compact, field deployable sensors that can measure winds and monitor pollution in the atmospheric boundary layer. Without these sensors they are unable to measure and make informed decisions about windborne dispersion of industrial emissions, environmental pollutants, and chemical/biological toxins under operational conditions. The project will develop eye-safe coherent lidar (light detection and ranging) systems that can measure wind velocities at ranges of up to 10 km with an accuracy of about 1 m/s, and can be deployed to field sites as required. The technology will be of major interest to the commercial sector.Read moreRead less
Advanced X-ray Optical Systems: From innovative idea to intelligent implementation. This project combines advances made in x-ray optics by the x-ray physics group at the University of Melbourne with sophisticated microfabrication techniques developed at Swinburne University of Technology and at the Argonne National Laboratory synchrotron. This fusion gives us immediate access into a major space science initiative - an x-ray telescope for the International Space Station. At the same time we will ....Advanced X-ray Optical Systems: From innovative idea to intelligent implementation. This project combines advances made in x-ray optics by the x-ray physics group at the University of Melbourne with sophisticated microfabrication techniques developed at Swinburne University of Technology and at the Argonne National Laboratory synchrotron. This fusion gives us immediate access into a major space science initiative - an x-ray telescope for the International Space Station. At the same time we will be building a kernel of excellence, based on new approaches to x-ray imaging, that will be strategically placed to become an integral part of the development of experimental facilities for the Australian Synchrotron.Read moreRead less
Across the Gravitational Wave Spectrum. Violent astrophysical events in the universe emit gravitational waves across a spectrum from mHz to kHz, producing an infinitesimal?but detectable'strain in space-time itself. Like high energy physics projects, gravitational wave detection involves giant multi million dollar research facilities and extensive international collaboration. This project will develop ideas, equipment and algorithms which will enhance the performance of both high frequency (gro ....Across the Gravitational Wave Spectrum. Violent astrophysical events in the universe emit gravitational waves across a spectrum from mHz to kHz, producing an infinitesimal?but detectable'strain in space-time itself. Like high energy physics projects, gravitational wave detection involves giant multi million dollar research facilities and extensive international collaboration. This project will develop ideas, equipment and algorithms which will enhance the performance of both high frequency (ground) and low frequency (space) based laser interferometer type detectors, and see Australia expand its already important role in searching for nature's most elusive signals.Read moreRead less
Intravital super-resolution imaging via Stimulated Emission Depletion microscopy (STED)-microendoscopy. We will develop a new technology to enable the imaging of sub-cellular structures within a biological specimen, with super-resolution. This intravital super-resolution imaging technology will build off world leading techniques to image objects with super-resolution and to perform this within a specimen, with minimal invasion. The broad ramifications of this technology apply to biology, medical ....Intravital super-resolution imaging via Stimulated Emission Depletion microscopy (STED)-microendoscopy. We will develop a new technology to enable the imaging of sub-cellular structures within a biological specimen, with super-resolution. This intravital super-resolution imaging technology will build off world leading techniques to image objects with super-resolution and to perform this within a specimen, with minimal invasion. The broad ramifications of this technology apply to biology, medical science, imaging and sensing. Important applications include the early detection of debilitating diseases and the advancement of understanding of cellular biology. This research will raise Australia's profile as a world leader in science and technology, building on our emerging presence in the biophysical sciences.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
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
A wavelength-versatile visible laser for ophthalmic instrumentation. Treatment of a wide range of retinal disorders can be enhanced by a range of treatment modalities using laser beams of different colours. The outcome of this project will be a new laser technology for ophthalmic applications which is unique in its versatility while reducing size and cost. This will allow our partner, Opto Global, to gain a unique market position for its ophthalmic products with flow-on benefits to the Austral ....A wavelength-versatile visible laser for ophthalmic instrumentation. Treatment of a wide range of retinal disorders can be enhanced by a range of treatment modalities using laser beams of different colours. The outcome of this project will be a new laser technology for ophthalmic applications which is unique in its versatility while reducing size and cost. This will allow our partner, Opto Global, to gain a unique market position for its ophthalmic products with flow-on benefits to the Australian economy and ultimately benefits to the community through improved clinical efficacy and patient outcomes. The frontier technology represented by these new laser devices is also applicable to other industries including medical aesthetics, colour projection and display, and defence systems.Read moreRead less