Generalized imaging systems incorporating hybrid hardware-software optics. Fundamental optics research underpins the commercial optical technologies of tomorrow. Modern examples of such evolution, from the fundamental to the commercial, include lasers, LED traffic lights, thin-screen computer monitors and digital cameras. The recent advent of accessible powerful computers, together with recent advances in optical physics, promise a powerful merging of computing and optical technologies into so ....Generalized imaging systems incorporating hybrid hardware-software optics. Fundamental optics research underpins the commercial optical technologies of tomorrow. Modern examples of such evolution, from the fundamental to the commercial, include lasers, LED traffic lights, thin-screen computer monitors and digital cameras. The recent advent of accessible powerful computers, together with recent advances in optical physics, promise a powerful merging of computing and optical technologies into so-called virtual optical systems in which the computer processes optical information in a manner very similar to lenses. In particular, the computer may be used to decode distorted images provided by an imperfect imaging system. 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.
Moving-beam phase retrieval - a route to better microscopy! This research will benefit the nation by improving the quality of x-ray diffraction and electron microscopy techniques available to Australian scientists. It will make it possible to examine microscopic structures in more detail and therefore gain more information about the atomic positions in these structures. This will greatly benefit research that depends on finding the structure of very small objects. Such research areas include ....Moving-beam phase retrieval - a route to better microscopy! This research will benefit the nation by improving the quality of x-ray diffraction and electron microscopy techniques available to Australian scientists. It will make it possible to examine microscopic structures in more detail and therefore gain more information about the atomic positions in these structures. This will greatly benefit research that depends on finding the structure of very small objects. Such research areas include nanomaterials, biological engineering, medical science and materials science. The work is also expected to have industrial applications and to make an important contribution to the development of the synchrotron science industry in Australia.Read moreRead less
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
Electron Tomography of Electromagnetic Fields, Potentials and Sources. The proliferation of technologies incorporating magnetic materials with exquisitely fine structure demands precise characterization methods, which are able to keep pace with magnetic miniaturization. However, existing techniques are unable to directly image magnetic materials at high resolution in three dimensions. We will overcome this deficiency, by combining an exciting new methodology for the three-dimensional visualisati ....Electron Tomography of Electromagnetic Fields, Potentials and Sources. The proliferation of technologies incorporating magnetic materials with exquisitely fine structure demands precise characterization methods, which are able to keep pace with magnetic miniaturization. However, existing techniques are unable to directly image magnetic materials at high resolution in three dimensions. We will overcome this deficiency, by combining an exciting new methodology for the three-dimensional visualisation of electromagnetic fields, with the latest cutting-edge electron-microscopes, thereby facilitating advances in magnetic nano-manufacturing. The anticipated applications are vast, from patterned nanomagnets and magnetic proteins, through to semiconductors and superconductors.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453521
Funder
Australian Research Council
Funding Amount
$508,374.00
Summary
National Heavy Ion Accelerator. The principal objectives are to develop a facility to provide energetic heavy ions for basic science, applications and research training. This will be accomplished through an enhancement of a superconducting linear accelerator using innovative technology, and extension of the available beam species through improvements to a large electrostatic tandem accelerator. The facility provides research resources for a broad range of national and international users.
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
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
Foundation studies of ion-beam nanotechnology. The impact of a single fast atom with sensitive materials leaves a path of latent damage with a diameter of around 10 nm. This latent damage can be developed to create nanostructures in a novel technique called ion beam nanomachining. We propose to create a method for using single atom impacts to produce nanomachined structures with novel physical and optical properties. This will be done by use of an active substrate that functions as a detector s ....Foundation studies of ion-beam nanotechnology. The impact of a single fast atom with sensitive materials leaves a path of latent damage with a diameter of around 10 nm. This latent damage can be developed to create nanostructures in a novel technique called ion beam nanomachining. We propose to create a method for using single atom impacts to produce nanomachined structures with novel physical and optical properties. This will be done by use of an active substrate that functions as a detector sensitive to single ion impacts. We propose to study the fundamental principles of this method.Read moreRead less
Quantum magnetometry on the microscale. This proposal will create a microscope for magnetic fields by measuring the quantum spin of a Bose-Einstein condensate at temperatures near absolute zero. Classical measurements of spin have underpinned transforming technologies, from magnetic resonance imaging to terabyte-scale hard-disc storage. We will make a truly quantum measurement of spin which will create a magnetic field microscope one million times more sensitive than the current state-of-the-art ....Quantum magnetometry on the microscale. This proposal will create a microscope for magnetic fields by measuring the quantum spin of a Bose-Einstein condensate at temperatures near absolute zero. Classical measurements of spin have underpinned transforming technologies, from magnetic resonance imaging to terabyte-scale hard-disc storage. We will make a truly quantum measurement of spin which will create a magnetic field microscope one million times more sensitive than the current state-of-the-art. The magnetic field microscope will be sensitive enough to measure fields from single biological cells and from superconducting nanosurfaces, giving critical new perspectives in biomedical research and next-generation electronics.Read moreRead less