Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775612
Funder
Australian Research Council
Funding Amount
$700,000.00
Summary
Nanomaterials Optical Characterisation Facility. Nanotechnology is expected to revolutionize a wide variety of fields, from medicine to agriculture, communications and electronics. However, the small length scales involved present significant challenges with regard to characterising the nanomaterials produced. The Nanomaterials Optical Characterisation facility will provide state-of-the-art equipment for examining the properties of nanomaterials. The equipment will be pivotal in assisting the de ....Nanomaterials Optical Characterisation Facility. Nanotechnology is expected to revolutionize a wide variety of fields, from medicine to agriculture, communications and electronics. However, the small length scales involved present significant challenges with regard to characterising the nanomaterials produced. The Nanomaterials Optical Characterisation facility will provide state-of-the-art equipment for examining the properties of nanomaterials. The equipment will be pivotal in assisting the development of next-generation medicines, implants, optical devices and surface coatings, further strengthening Australia's formidable reputation in these areas.Read moreRead less
A Method to Characterise an Aberration-Corrected Electron Wave Field - a step towards quantitative electron microscopy. Australia has recently invested in a powerful, new electron microscope, one of the first in the world, which can image features at the atomic scale that could not be seen before. This project will forge a strategic partnership with the designer and the distributor of this microscope, to develop special new methods that will further increase the microscope's imaging power. This ....A Method to Characterise an Aberration-Corrected Electron Wave Field - a step towards quantitative electron microscopy. Australia has recently invested in a powerful, new electron microscope, one of the first in the world, which can image features at the atomic scale that could not be seen before. This project will forge a strategic partnership with the designer and the distributor of this microscope, to develop special new methods that will further increase the microscope's imaging power. This will give Australian scientists unique capabilities with which to investigate and engineer new materials for advanced technological applications and it will train young Australian scientists in these cutting-edge techniques.Read moreRead less
The first critical tests of many-body and correlated Quantum Electro-Dynamics (QED) in medium-Z atomic systems. Major difficulties are being encountered in the computation of high-order and correlated terms of Quantum Electro-Dynamical effects in atoms. We will make the first measurements for medium-Z atoms critically sensitive to two-electron QED, and the first tests of QED in this region accurate to 1%. This accuracy will allow new insight into two-electron systems, theoretical approaches, and ....The first critical tests of many-body and correlated Quantum Electro-Dynamics (QED) in medium-Z atomic systems. Major difficulties are being encountered in the computation of high-order and correlated terms of Quantum Electro-Dynamical effects in atoms. We will make the first measurements for medium-Z atoms critically sensitive to two-electron QED, and the first tests of QED in this region accurate to 1%. This accuracy will allow new insight into two-electron systems, theoretical approaches, and recent observed discrepancies between QED theory and experiment. This proposal follows recent successful experimental work using new capabilities of Electron-Beam Ion Traps (EBITs). Our recent publications have proven that this novel approach can yield new insight into the interaction of light with matter.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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989390
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Versatile Scanning X-ray Microscopy Facility at the Australian Synchrotron. The challenges of the modern world means that the Australian community must continue to have access to state of the art research tools. An important component of international synchrotron sources is the very high resolution x-ray microscope. These microscopes are used to image samples of biological, material or environmental significance with extraordinary precision. This project will establish such a microscope at the A ....Versatile Scanning X-ray Microscopy Facility at the Australian Synchrotron. The challenges of the modern world means that the Australian community must continue to have access to state of the art research tools. An important component of international synchrotron sources is the very high resolution x-ray microscope. These microscopes are used to image samples of biological, material or environmental significance with extraordinary precision. This project will establish such a microscope at the Australian Synchrotron in Clayton, and nucleates an extensive nationwide collaboration that is devoted to the development of this and related techniques and their application to problems of national scientific, environmental and technological importance.Read moreRead less
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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668482
Funder
Australian Research Council
Funding Amount
$485,000.00
Summary
X-ray micro-tomography facility. This proposal identifies a new area of importance in the investigation of the function and structure of materials as diverse as muscle and metal coatings - the ability to quantify the physical structure of an object. Researchers can further couple that ability with existing facilities at La Trobe University, which allow the chemical makeup on an interface to be analysed. The planned research projects will benefit the community in applications ranging from compos ....X-ray micro-tomography facility. This proposal identifies a new area of importance in the investigation of the function and structure of materials as diverse as muscle and metal coatings - the ability to quantify the physical structure of an object. Researchers can further couple that ability with existing facilities at La Trobe University, which allow the chemical makeup on an interface to be analysed. The planned research projects will benefit the community in applications ranging from composite and light-weight materials for aerospace, metal coatings for automotive and tool manufacture and tissue engineering for artificial heart valves. This breadth of application ensures a truly multidisciplinary training environment for students in contact with the facility.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
High-resolution electron diffraction imaging for the nanosciences. This project will develop new ways of seeing structure at the atomic level, to yield new imaging approaches needed for frontier developments in nano-science and nanotechnology. These areas are critical to Australia's future economic development and it is only through significant improvements in imaging capacity that we will be able to sustain this country's outstanding record in scientific innovation. The project will obtain inte ....High-resolution electron diffraction imaging for the nanosciences. This project will develop new ways of seeing structure at the atomic level, to yield new imaging approaches needed for frontier developments in nano-science and nanotechnology. These areas are critical to Australia's future economic development and it is only through significant improvements in imaging capacity that we will be able to sustain this country's outstanding record in scientific innovation. The project will obtain intellectual leverage from the expertise of the team of Chief Investigators, utilizing state-of-the-art infrastructure available in Australia and abroad, and provide a professional and broad training environment for our best and brightest graduate students.Read moreRead less