Producing optimally short pulses at long wavelengths. This project aims to make the fluoride glass fibre platform the preferred material for generating ultrashort pulses at 2.8 nm and beyond. High power and efficiency from simple device architectures are essential for industry, medicine and defence. Modern sources of short pulses of light emitting mid-infrared wavelengths are complicated and inefficient. This project will improve fibre sources emitting short pulses and create the essential build ....Producing optimally short pulses at long wavelengths. This project aims to make the fluoride glass fibre platform the preferred material for generating ultrashort pulses at 2.8 nm and beyond. High power and efficiency from simple device architectures are essential for industry, medicine and defence. Modern sources of short pulses of light emitting mid-infrared wavelengths are complicated and inefficient. This project will improve fibre sources emitting short pulses and create the essential building blocks for future all-fibre arrangements that will be more robust. The sources are expected to have applications in non-linear optics and materials modification.Read moreRead less
In vivo molecular imaging using engineered affinity reagents and fluorescent laser scanning confocal endomicroscopy. The goal of this project is to develop laser scanning confocal endomicroscopy as a tool for basic scientific discovery and rapid detection of disease biomarkers. The cutting-edge instrument and associated technologies will provide scientists with unprecedented access to dynamic biological processes as they occur in real-time. In addition, it will enable the development of virtual ....In vivo molecular imaging using engineered affinity reagents and fluorescent laser scanning confocal endomicroscopy. The goal of this project is to develop laser scanning confocal endomicroscopy as a tool for basic scientific discovery and rapid detection of disease biomarkers. The cutting-edge instrument and associated technologies will provide scientists with unprecedented access to dynamic biological processes as they occur in real-time. In addition, it will enable the development of virtual biopsies and instant diagnosis without the need for costly and time-consuming histopathological reports. Thus, it will not only drive transformative research but also transform health care delivery. It will also be a major boost to the Australian biotechnology industry with potential for enormous economic benefits.Read moreRead less
Beyond Spectral Detection: Engineering SUPER Dot Probes for High-Throughput Discovery. Molecules that are altered as a result of a pathological condition are generally present in very low abundance, and pose a “needle-in-a-haystack” problem. Current detection, quantification and localisation technologies use fluorescent probes that are limited by sensitivity and analysis time. This project will develop a new generation of nanophotonic luminescent probes (Strong Upconversion Photo-stable Encoded ....Beyond Spectral Detection: Engineering SUPER Dot Probes for High-Throughput Discovery. Molecules that are altered as a result of a pathological condition are generally present in very low abundance, and pose a “needle-in-a-haystack” problem. Current detection, quantification and localisation technologies use fluorescent probes that are limited by sensitivity and analysis time. This project will develop a new generation of nanophotonic luminescent probes (Strong Upconversion Photo-stable Encoded nano-Radiators (SUPER) Dots), based on purpose-engineered up-conversion nanocrystals that are ultra-bright and have low background interference, high specificity, speed, and large-scale multiplexing capacity. These probes will allow microscopy and flow cytometry to measure hitherto undetectable rare-event molecules and cells, opening new frontiers for the discovery of new biomarkers.Read moreRead less
Through a glass brightly: opening up the mid-infrared using dysprosium ions. By exploiting the dysprosium ion in a unique and practical way, the project will create high power mid-infrared light with unprecedented optical efficiency. The project will make use of the unusually wide fluorescence spectrum of the dysprosium ion to produce stable and bandwidth-limited ultra-fast light pulses in the mid-infrared. The proposed light sources will have application in mid-infrared nonlinear optics and wil ....Through a glass brightly: opening up the mid-infrared using dysprosium ions. By exploiting the dysprosium ion in a unique and practical way, the project will create high power mid-infrared light with unprecedented optical efficiency. The project will make use of the unusually wide fluorescence spectrum of the dysprosium ion to produce stable and bandwidth-limited ultra-fast light pulses in the mid-infrared. The proposed light sources will have application in mid-infrared nonlinear optics and will benefit medicine, defence, fundamental physics and manufacturing providing excellent opportunities for Australian research, industry and collaboration.Read moreRead less
Advanced Hybrid Fibres for Functional Biomedical Imaging. This project expects to develop new techniques and devices for biomedical imaging. Biomedical imaging is widely used for medical diagnosis and treatment, with different types of imaging providing different information. This project aims to develop techniques that will allow imaging using safer nonionising terahertz radiation, with better resolution than ever before. It plans to combine this with optical, visible and infrared imaging to gi ....Advanced Hybrid Fibres for Functional Biomedical Imaging. This project expects to develop new techniques and devices for biomedical imaging. Biomedical imaging is widely used for medical diagnosis and treatment, with different types of imaging providing different information. This project aims to develop techniques that will allow imaging using safer nonionising terahertz radiation, with better resolution than ever before. It plans to combine this with optical, visible and infrared imaging to give very broad spectral information. It also aims to develop probes for direct interfacing to tissue to collect and deliver electrical signals, light and fluids, and to image neural activity. The intended outcome of the project is to allow single cancer cells within tissue to be identified to allow early stage cancer detection, and to develop implantable devices for neuroscience research and pain management.Read moreRead less
Rapid detection of rare-event cells by strong UP-conversion
encoded nano-radiators (SUPER Dots): finding a needle in a haystack. Current diagnostic tests are not sensitive enough to detect cancer in its very early stages or early recurrence following treatment. The new technologies developed by this project will be able to find single cancer cells in blood and urine samples heralding a new era in medical diagnostics.
A brighter future: the pure-quartic soliton laser. This project aims to build an innovative, ultrafast laser based on the recent discovery of pure-quartic solitons, a new class of optical soliton. Investigating these solitons in their own right will provide new insights into the physics of soliton formation and propagation. The concept of the pure-quartic soliton laser is expected to lead to the transformation of ultrafast science and related applications with the benefit of to improving efficie ....A brighter future: the pure-quartic soliton laser. This project aims to build an innovative, ultrafast laser based on the recent discovery of pure-quartic solitons, a new class of optical soliton. Investigating these solitons in their own right will provide new insights into the physics of soliton formation and propagation. The concept of the pure-quartic soliton laser is expected to lead to the transformation of ultrafast science and related applications with the benefit of to improving efficiency, and significantly reducing the cost of high-energy ultrafast lasers. The project aims to provide benefits in ultrafast science, industrial materials processing, laser surgery, and molecular spectroscopy.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100159
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
National facility for biased target deposition of alloyed nanolayers. This facility will enhance Australia's strengths and capabilities in fabricating structures, with applications in multiple research fields including opto-magneto-electronics, next generation lithium ion batteries and energy nanogenerators. It will enhance Australia's research profile as a leader in nanotechnology.
Laser emission at the limit of glass transparency using nanocrystal doping . We will create a new composite glass providing strong fluorescence which fully exploits the high transmission of glass in the mid-infrared. When combined with emerging rare earth ion transitions and precise excitation processes, this project will help solve an important problem in optics; that the overall efficiency and power produced from deep mid-infrared light sources is not sufficient for all industries. The primary ....Laser emission at the limit of glass transparency using nanocrystal doping . We will create a new composite glass providing strong fluorescence which fully exploits the high transmission of glass in the mid-infrared. When combined with emerging rare earth ion transitions and precise excitation processes, this project will help solve an important problem in optics; that the overall efficiency and power produced from deep mid-infrared light sources is not sufficient for all industries. The primary outcome will be a series of robust fibre-based gain modules suitable for high power and very short optical pulses in the mid-infrared. These light sources will beneficially impact medicine, defence, sensing and manufacturing providing excellent opportunities for increasing Australian productivity and global competitiveness. Read moreRead less
Smart surfaces for monitoring cellular activity in real time: from multiple to single cells. Cells are the fundamental building block of life. In the proposed research smart surfaces will be developed that can monitor the release of enzymes from single cells and from multiple cells. This work will be important for developing cell chips for drug discovery, toxin detection and biomedical research and devices to monitor infection.