Quantitative polarisation phase microscopy: A new tool for advances in structural analysis and biophotonics. Innovation in biomedical research is driven by technology in optical imaging. Optical imaging methods including polarisation microscopy are widely accepted and are at the forefront of biomedical scientific discoveries. This project undertakes fundamental and applied research innovatively combining polarisation imaging and quantitative phase imaging microscopy to uniquely quantify the phys ....Quantitative polarisation phase microscopy: A new tool for advances in structural analysis and biophotonics. Innovation in biomedical research is driven by technology in optical imaging. Optical imaging methods including polarisation microscopy are widely accepted and are at the forefront of biomedical scientific discoveries. This project undertakes fundamental and applied research innovatively combining polarisation imaging and quantitative phase imaging microscopy to uniquely quantify the physical thickness and morphology of birefringent specimens such as the cardiac muscle cell. This project, while of substantial intellectual merit in its own right, could also have the potential to lead to the detection of the mechanisms related to heart failure. 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
Non-Interferometric Phase Measurement of Exotic Waves. Phase is a key concept in all aspects of physics from biological microscopy through to length measurement and on to industrial inspection. The University of Melbourne has developed a new class of phase measurement techniques that possesses unprecedented flexibility. The aim of this project is to build on the international leadership of the Australian team so as to fully explore and develop these techniques.
Developments in Optical Sciences. The applicant leads a highly motivated and successful group of young investigators doing internationally leading work on complete recovery of phase information. This work is able to provide new approaches to fundamental research problems at the basis of quantum mechanics, as well as leading to important new applications in biomedical and industrial imaging. The proposed work has already led to one start-up company and it is expected that the commercial developme ....Developments in Optical Sciences. The applicant leads a highly motivated and successful group of young investigators doing internationally leading work on complete recovery of phase information. This work is able to provide new approaches to fundamental research problems at the basis of quantum mechanics, as well as leading to important new applications in biomedical and industrial imaging. The proposed work has already led to one start-up company and it is expected that the commercial development will continue. The proposed program will lead to an involvement in an international space project, enhance synchrotron-based research in Australia and lead to new developments in microfabrication technologies.Read moreRead less
Active Control of Light for Nonlinear Photonic Devices. In free space, light travels in a straight line, but since ancient times mankind has always sought to direct its propagation. Controlling light is an enduring problem in modern photonic technologies. The ultimate goal is to actively manipulate light propagation in space and time with a great accuracy. With this project we will investigate the fundamental science of active control of light in periodic structures and will provide a unique pla ....Active Control of Light for Nonlinear Photonic Devices. In free space, light travels in a straight line, but since ancient times mankind has always sought to direct its propagation. Controlling light is an enduring problem in modern photonic technologies. The ultimate goal is to actively manipulate light propagation in space and time with a great accuracy. With this project we will investigate the fundamental science of active control of light in periodic structures and will provide a unique platform for exploration of ground breaking optical physics, ensuring Australia remains a world leader in the field. Precision manipulation of light will form the basis of new techniques for all-optical signal processing and computing, with great impact on Australian photonic and defense industries.Read moreRead less
Improved fibre Bragg grating sensors for detection of structural hot spots. Structural integrity monitoring, to anticipate and prevent failure, is a multi-billion dollar effort worldwide. Detailed assessment of the capability of fibre Bragg gratings to measure strain profiles along the grating length, i.e. intragrating sensing, and thereby detect structural ?hot spots? before failure is essential for effective systems. They will be used to determine strain gradients similar to those found in com ....Improved fibre Bragg grating sensors for detection of structural hot spots. Structural integrity monitoring, to anticipate and prevent failure, is a multi-billion dollar effort worldwide. Detailed assessment of the capability of fibre Bragg gratings to measure strain profiles along the grating length, i.e. intragrating sensing, and thereby detect structural ?hot spots? before failure is essential for effective systems. They will be used to determine strain gradients similar to those found in common problem areas, such as the tips of elliptic notches and disbonding at the ends of composite joints. Additionally, grating refractive index profiles will be characterised using imaging techniques, to assess performance and possible changes to gratings after prolonged use.Read moreRead less
Advancing x-ray imaging into new dimensions using interferometry and phase-space tomography. Synchrotron science and nanofabrication technologies are priority investment areas for most industrial countries including Australia. This research program takes advantages of recent progress in these fields and aims to advance x-ray imaging techniques of high sensitivity and low radiation dose and retrieve all extractable information of an object encoded in a wavefield. The development of these techniqu ....Advancing x-ray imaging into new dimensions using interferometry and phase-space tomography. Synchrotron science and nanofabrication technologies are priority investment areas for most industrial countries including Australia. This research program takes advantages of recent progress in these fields and aims to advance x-ray imaging techniques of high sensitivity and low radiation dose and retrieve all extractable information of an object encoded in a wavefield. The development of these techniques is critical to future opportunities of frontier discoveries of the biological, nano and atomic world. Its application includes structural biology, medical diagnosis, biomedicine, material sciences and many other fields.Read moreRead less
Multi-dimensional optical data storage based on nanophotonics - the third generation optical data storage technology. The key-sector in high tech markets has been the photonics industry over the last decade, and it will continue to revolutionise our ways of information storage, processing and transfer for the next 10 to 20 years. The current project of high-capacity Petabyte optical data storage, i.e the third generation optical data storage, will prove to be the key technological innovation in ....Multi-dimensional optical data storage based on nanophotonics - the third generation optical data storage technology. The key-sector in high tech markets has been the photonics industry over the last decade, and it will continue to revolutionise our ways of information storage, processing and transfer for the next 10 to 20 years. The current project of high-capacity Petabyte optical data storage, i.e the third generation optical data storage, will prove to be the key technological innovation in photonics (one of the National Research Priorities), which will not only meet the growing demands of the consumer market, but also continue to drive the industry and create new markets. This is in line with the Priority Goals set by the Minister for Education, Science and Training, as it will put Australia into the unique position in the information age. Read moreRead less
Nano-photonic fabrication and storage using near-field super-resolving probes. The aim of the project is to develop a novel near-field storage device and nano-fabrication instruments, which are based on the super-resolution technique. As a result, the new storage device has a density 100 times of the current DVD technology. The nano-fabrication techniques can be used for all optics devices of nanometer resolution for fast information transferring. This project extends the key developments in t ....Nano-photonic fabrication and storage using near-field super-resolving probes. The aim of the project is to develop a novel near-field storage device and nano-fabrication instruments, which are based on the super-resolution technique. As a result, the new storage device has a density 100 times of the current DVD technology. The nano-fabrication techniques can be used for all optics devices of nanometer resolution for fast information transferring. This project extends the key developments in the field of nano-photonics and will put Australia in a uniquely strong position in the internationally competitive information technology field.Read moreRead less
Development of three-dimensional high-density optical data storage and photonic crystals in photo-polymers with a superresolution imaging system. The aim of this project is to develop a three-dimensional (3-D) high-density optical data storage method and photonic crystals in photo-polymers using a superresolution imaging system. As a result, it is possible to produce a 3-D data density of approximately 10 Tbits/cm3 in low-cost and erasable photo-polymers, equivalent to 3000 times the information ....Development of three-dimensional high-density optical data storage and photonic crystals in photo-polymers with a superresolution imaging system. The aim of this project is to develop a three-dimensional (3-D) high-density optical data storage method and photonic crystals in photo-polymers using a superresolution imaging system. As a result, it is possible to produce a 3-D data density of approximately 10 Tbits/cm3 in low-cost and erasable photo-polymers, equivalent to 3000 times the information in a current digital video disc (DVD). 3-D polymer-based photonic crystals will provide fast, low-cost and compact all-optics devices for optical computing technology. Consequently, the capacity and speed of information super-highways will be significantly increased, which enhances the internationally competitive ability of Australia in information technology.Read moreRead less