Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775546
Funder
Australian Research Council
Funding Amount
$370,000.00
Summary
Construction of the blue-arm of the ANU 2.3m telescope Wide-Field Spectrograph. The new blue and red arms of the WiFeS spectrograph on the SSO 2.3m telescope utilizes new optical techniques and advances in detector technology to provide unique capabilities for front-line research and student training. The novel integral field units on WiFeS extract spectra across the face of faint, distant galaxies enabling the dynamics of the stellar and gas content to be analysed in unprecedented detail. Anoth ....Construction of the blue-arm of the ANU 2.3m telescope Wide-Field Spectrograph. The new blue and red arms of the WiFeS spectrograph on the SSO 2.3m telescope utilizes new optical techniques and advances in detector technology to provide unique capabilities for front-line research and student training. The novel integral field units on WiFeS extract spectra across the face of faint, distant galaxies enabling the dynamics of the stellar and gas content to be analysed in unprecedented detail. Another important project will be to follow-up interesting objects discovered by the new SkyMapper telescope and establish those that need to be observed on 8 m telescopes such as Gemini, Magellan or VLT. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453879
Funder
Australian Research Council
Funding Amount
$184,163.00
Summary
Electron beam induced deposition and ablation nanofabrication facility. Electron beam induced deposition and ablation(EBIDA) is rapidly emerging as a new technology capable of fabricating three-dimensional nanostructures on nearly any substrate with very high precision. This proposal aims to establish a nanoscale EBIDA facility by integrating a specialized nanolithography attachment with an existing state-of-the-art 1nm resolution high current variable pressure scanning electron microscope. This ....Electron beam induced deposition and ablation nanofabrication facility. Electron beam induced deposition and ablation(EBIDA) is rapidly emerging as a new technology capable of fabricating three-dimensional nanostructures on nearly any substrate with very high precision. This proposal aims to establish a nanoscale EBIDA facility by integrating a specialized nanolithography attachment with an existing state-of-the-art 1nm resolution high current variable pressure scanning electron microscope. This combination of instrumentation will enable the high-speed production of conductive and insulating structures with 1-to-10nm dimensions. The unique facility will be used to manufacture and prototype novel nanoscale devices and structures and will enable measurement of their physical and chemical properties.Read moreRead less
Star Formation at Millimetre Wavelengths with the CSIRO Australia Telescope. The newly-upgraded CSIRO Australia Telescope Compact Array, together with the CSIRO Mopra Telescope, provide a unique and powerful combination for studying the millimetre-wave emission from molecules and cold dust in star formation regions. We propose to combine the astrophysical expertise of UNSW with the instrumental expertise of CSIRO to use these instruments to study the processes of star formation. There are two pa ....Star Formation at Millimetre Wavelengths with the CSIRO Australia Telescope. The newly-upgraded CSIRO Australia Telescope Compact Array, together with the CSIRO Mopra Telescope, provide a unique and powerful combination for studying the millimetre-wave emission from molecules and cold dust in star formation regions. We propose to combine the astrophysical expertise of UNSW with the instrumental expertise of CSIRO to use these instruments to study the processes of star formation. There are two parallel themes to this research: to commission and develop optimal techniques for using the new instruments, and to make use of them to explore the poorly-understood processes that cause stars to form.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347403
Funder
Australian Research Council
Funding Amount
$222,000.00
Summary
An ultra-wideband digital filterbank for the Mopra Radiotelescope. We seek funding to equip the Mopra radiotelescope with an ultra-wide-bandwidth digital filter bank. This will greatly improve the efficiency of the observatory, increasing the speed at which spectroscopic data is acquired by a factor of 8, and the speed of acquiring continuum data by a factor of 32. Once equipped in this way, Mopra, which is already the largest millimetre-wave radiotelescope in the southern hemisphere, will enjo ....An ultra-wideband digital filterbank for the Mopra Radiotelescope. We seek funding to equip the Mopra radiotelescope with an ultra-wide-bandwidth digital filter bank. This will greatly improve the efficiency of the observatory, increasing the speed at which spectroscopic data is acquired by a factor of 8, and the speed of acquiring continuum data by a factor of 32. Once equipped in this way, Mopra, which is already the largest millimetre-wave radiotelescope in the southern hemisphere, will enjoy an unbeatable edge over all other competing observatories around the world through its combination of collecting area and bandpass.Read moreRead less
Exploring the last frontier: cosmic reionization and the first galaxies. This program will help to position Australia as a leader in the development of the Square Kilometre Array, a 1.5 billion Euro radio telescope that Australia is vying to host. The program takes advantage of the uniquely radio quiet environment of Western Australia to achieve unprecedented measurements of the 'first light fossils' in the Universe, which reside in the portion of the radio spectrum that is filled by FM radio tr ....Exploring the last frontier: cosmic reionization and the first galaxies. This program will help to position Australia as a leader in the development of the Square Kilometre Array, a 1.5 billion Euro radio telescope that Australia is vying to host. The program takes advantage of the uniquely radio quiet environment of Western Australia to achieve unprecedented measurements of the 'first light fossils' in the Universe, which reside in the portion of the radio spectrum that is filled by FM radio transmissions in most parts of the planet. This ground-breaking research program will provide training for the next generation of world-class scientists and add to the already high profile of Australian astrophysics.Read moreRead less
Technologies for advanced optical fibre sensors. This project is to create a significantly better technology for exploration of oil and gas reserves under the ocean. Based on lasers and fibre optics, it leverages Australia's prodigious photonics expertise and couples it with Australia's established and well-regarded resource industry. Successful completion will enable better utilization of this country's natural resources, in particular oil and gas reserves, whilst also creating a high technolog ....Technologies for advanced optical fibre sensors. This project is to create a significantly better technology for exploration of oil and gas reserves under the ocean. Based on lasers and fibre optics, it leverages Australia's prodigious photonics expertise and couples it with Australia's established and well-regarded resource industry. Successful completion will enable better utilization of this country's natural resources, in particular oil and gas reserves, whilst also creating a high technology export, given the size of the world marine survey market (US$4 billion). Better energy exploration technologies are vital to Australia and, indeed the world, as energy supply dwindles and the increased energy costs begin to impact negatively on economic growth.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0237527
Funder
Australian Research Council
Funding Amount
$170,000.00
Summary
Bioscope IV : Advanced Scanned Probe Microscopy. The Atomic Force Microscope presents a unique view of the microscopic and molecular world, for it is sensitive to force alone. This instrument can accurately map force over a surface at the molecular scale; picoNewtons at nanometre resolution. The host of intermolecular forces which cause phenomena such as self-assembly, colloid stability, cell interactions and friction are only directly measurable with this technique. In this field of force meas ....Bioscope IV : Advanced Scanned Probe Microscopy. The Atomic Force Microscope presents a unique view of the microscopic and molecular world, for it is sensitive to force alone. This instrument can accurately map force over a surface at the molecular scale; picoNewtons at nanometre resolution. The host of intermolecular forces which cause phenomena such as self-assembly, colloid stability, cell interactions and friction are only directly measurable with this technique. In this field of force measurement Australian researchers are leaders. The proposed instrument expands the capabilities of this effort, and develops exciting new directions including the direct manipulation of molecules through a novel feedback and control (haptic) interface.Read moreRead less
Alpha-particle cluster structure in light nuclei: helping and hindering fusion? A new, efficient detector system will be designed and built to answer a question never before asked - can the special structures of carbon, resembling three alpha-particles, assist rather than hinder the process of fusion with heavy nuclei? This question has arisen through my recent work published in Nature, which showed that in reactions with heavy nuclei, paradoxically both fusion and break-up into alpha-particles ....Alpha-particle cluster structure in light nuclei: helping and hindering fusion? A new, efficient detector system will be designed and built to answer a question never before asked - can the special structures of carbon, resembling three alpha-particles, assist rather than hinder the process of fusion with heavy nuclei? This question has arisen through my recent work published in Nature, which showed that in reactions with heavy nuclei, paradoxically both fusion and break-up into alpha-particles are more likely for carbon than for neighbouring nuclei. These results defy interpretation within the standard theory of nuclear fusion. The project will help to maintain Australia's world-leading position in the study of nuclear fusion.
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Reaching the superheavy elements: a new approach with a novel ultra-sensitive detector array. Our project aims to build the knowledge base underpinning the creation of new heavy elements and isotopes. This first direct investigation of the hoped-for benefits of using radioactive beams will enhance the strong reputation of Australian research in the fundamental subject of nuclear fusion. The unique and sophisticated scientific instrument to be developed will enhance the capability of our RIEF-fun ....Reaching the superheavy elements: a new approach with a novel ultra-sensitive detector array. Our project aims to build the knowledge base underpinning the creation of new heavy elements and isotopes. This first direct investigation of the hoped-for benefits of using radioactive beams will enhance the strong reputation of Australian research in the fundamental subject of nuclear fusion. The unique and sophisticated scientific instrument to be developed will enhance the capability of our RIEF-funded fusion product separator at the ANU, and use at overseas radioactive beam accelerators will showcase Australian technological achievement. This early participation in exciting, leading-edge developments will help Australian researchers to make full use of future, intense radioactive beam facilities, both in pure and applied research. Read moreRead less
Development of Advanced Detection Systems for Accelerator Mass Spectrometry. This project aims to expand significantly the range of isotopes available for accelerator mass spectrometry at the Australian National University to include the ability to detect manganese-53, nickel-59 and uranium-236 to ultra-sensitive concentrations. To achieve this, my extensive experience in fundamental nuclear physics will be exploited to develop a gas-filled magnet for the detection of mangnese-53 and nickel-59, ....Development of Advanced Detection Systems for Accelerator Mass Spectrometry. This project aims to expand significantly the range of isotopes available for accelerator mass spectrometry at the Australian National University to include the ability to detect manganese-53, nickel-59 and uranium-236 to ultra-sensitive concentrations. To achieve this, my extensive experience in fundamental nuclear physics will be exploited to develop a gas-filled magnet for the detection of mangnese-53 and nickel-59, and a time-of-flight detector to detect uranium-236. This project has applications in the topical areas of climate change and nuclear safeguards, as well as applications in the earth sciences and the management of nuclear waste.Read moreRead less