Linear Formation Interferometry for Astrophysics and New Space Technologies. This project will prototype a new type of visible and infrared light interferometry: telescopes freely moving in a line 10s of metres in length and directing their light towards a central beam combiner. This is particularly well suited to sparse aperture optical interferometry from space, which can be used to resolve angular scales much finer than the world's largest monolithic telescopes. The ground based prototype wil ....Linear Formation Interferometry for Astrophysics and New Space Technologies. This project will prototype a new type of visible and infrared light interferometry: telescopes freely moving in a line 10s of metres in length and directing their light towards a central beam combiner. This is particularly well suited to sparse aperture optical interferometry from space, which can be used to resolve angular scales much finer than the world's largest monolithic telescopes. The ground based prototype will also be able to make a several key astrophysical observations of benchmark stars and stellar systems, including making precise polarimetric measurements of dust shells around bright stars.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100953
Funder
Australian Research Council
Funding Amount
$405,000.00
Summary
Directly imaging exoplanets with astrophotonic innovation. Understanding our place in the universe and the possibility of life are profound questions. This project aims to develop innovative astro-photonic technologies to enable imaging of Earth-like planets beyond our solar system, and to perform unprecedented observations. The project expects to generate new knowledge and innovation in exoplanet science and photonics. Expected outcomes include the first glimpse of the most Earth-like planet to ....Directly imaging exoplanets with astrophotonic innovation. Understanding our place in the universe and the possibility of life are profound questions. This project aims to develop innovative astro-photonic technologies to enable imaging of Earth-like planets beyond our solar system, and to perform unprecedented observations. The project expects to generate new knowledge and innovation in exoplanet science and photonics. Expected outcomes include the first glimpse of the most Earth-like planet to date, and the development of ground-breaking technology. Benefits include technological innovation — benefiting fields such as remote-sensing, space-communications, life-science imaging, as well as astronomy — and revealing key insights into our planet’s history and the potential for life in the universe.Read moreRead less
ARC Centre of Excellence for Gravitational Wave Discovery. This Centre aims to explore the historic first detections of gravitational waves to understand the extreme physics of black holes and warped spacetime, and inspire the next generation of Australian scientists and engineers. The next-generation gravity wave detectors will enable a thousand-fold increase in detection volume and result in the new gravitational wave discoveries, triggering a new era of gravitational wave astrophysics. Buil ....ARC Centre of Excellence for Gravitational Wave Discovery. This Centre aims to explore the historic first detections of gravitational waves to understand the extreme physics of black holes and warped spacetime, and inspire the next generation of Australian scientists and engineers. The next-generation gravity wave detectors will enable a thousand-fold increase in detection volume and result in the new gravitational wave discoveries, triggering a new era of gravitational wave astrophysics. Building on decades of Australian investment in gravitational wave and pulsar science, this Centre will coalesce research activities into a focussed national programme whose discoveries are intended to experimentally validate Einstein’s General Theory of Relativity and educate the public about the wonders of Einstein's Universe.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100015
Funder
Australian Research Council
Funding Amount
$1,680,000.00
Summary
The Cherenkov Telescope Array - From Production towards Operation. The Cherenkov Telescope Array is a transformational facility in very-high-energy gamma-ray astronomy. It will be 10 times more sensitive than current instruments and will revolutionise many topics in high energy astrophysics, and in astro-particle physics such as dark matter. Over 1000 scientists from over 30 countries are involved and the first telescopes on the southern hemisphere site in Chile will be installed from about 2021 ....The Cherenkov Telescope Array - From Production towards Operation. The Cherenkov Telescope Array is a transformational facility in very-high-energy gamma-ray astronomy. It will be 10 times more sensitive than current instruments and will revolutionise many topics in high energy astrophysics, and in astro-particle physics such as dark matter. Over 1000 scientists from over 30 countries are involved and the first telescopes on the southern hemisphere site in Chile will be installed from about 2021. This project will ensure Australia's contribution to complete the facility, leading into its operations phase (starting in 2027). It will also fund unique optical astronomy hardware that will enable Australian scientific leadership in supporting some of the Cherenkov Telescope Array's Key Science Projects.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100104
Funder
Australian Research Council
Funding Amount
$1,390,000.00
Summary
The Cherenkov Telescope Array - Production phase. This project aims to ensure Australia’s contribution to the five-year production phase of the Cherenkov Telescope Array (CTA), a very high energy gamma-ray astronomy instrument that is expected to transform both high energy astrophysics and astro-particle physics. Gamma-ray astronomy probes extreme processes in the Universe such as exploding stars, black holes, and mysterious dark matter. The project will maintain Australian access to all data an ....The Cherenkov Telescope Array - Production phase. This project aims to ensure Australia’s contribution to the five-year production phase of the Cherenkov Telescope Array (CTA), a very high energy gamma-ray astronomy instrument that is expected to transform both high energy astrophysics and astro-particle physics. Gamma-ray astronomy probes extreme processes in the Universe such as exploding stars, black holes, and mysterious dark matter. The project will maintain Australian access to all data and key science programmes of the CTA. Australian astronomers will be able to directly influence the major astrophysics goals of CTA, and link in with Australia's flagship astronomical infrastructure. This is expected to benefit astrophysics, big data processing, electronics, atmospheric physics and optics.Read moreRead less
How do galaxies get their gas? This project aims to build new understanding about the fundamental physics behind how galaxies get their gas. The way gas is accreted in galaxies affects how stars are made and what galaxies look like, including our own milky way. This project expects to build a new robotic instrument for three dimensional spectroscopy of galaxies, called Hector-I, to establish and run the Hector Galaxy Survey, the largest of its kind ever conducted. This survey data set will under ....How do galaxies get their gas? This project aims to build new understanding about the fundamental physics behind how galaxies get their gas. The way gas is accreted in galaxies affects how stars are made and what galaxies look like, including our own milky way. This project expects to build a new robotic instrument for three dimensional spectroscopy of galaxies, called Hector-I, to establish and run the Hector Galaxy Survey, the largest of its kind ever conducted. This survey data set will underpin broad investigations of gas accretion and the impact on the physical properties of galaxies. The project will clarify why our own galaxy looks so different to others, demonstrate Australian technologies for future commercialisation on international facilities, and train students for a high quality workforce.Read moreRead less
Life among giants: Jovian exoplanets and the habitable zone. How and where do gas giant planets like Jupiter form? The best answers would come from direct studies of the cradles of planetary birth themselves. This project takes direct aim at the forbidding technological challenge to recover the first images of planetary birth at the required scales of size (around Jupiter's orbit) and contrast. In revealing the architecture of formation of the giants, we simultaneously make an enormous stride in ....Life among giants: Jovian exoplanets and the habitable zone. How and where do gas giant planets like Jupiter form? The best answers would come from direct studies of the cradles of planetary birth themselves. This project takes direct aim at the forbidding technological challenge to recover the first images of planetary birth at the required scales of size (around Jupiter's orbit) and contrast. In revealing the architecture of formation of the giants, we simultaneously make an enormous stride in understanding the potential for habitable rocky worlds such as Earth, whose orbits will be dictated by the Jovians. Our program is driven by unique and innovative photonics technologies integrated within the best modern telescope facilities, allowing us to open a new window in exoplanetary science.Read moreRead less
Formation and evolution of planetary systems. This project aims to develop computer simulation methods and mathematical modelling to help solve the mystery of how planets form. The project should also produce world-first algorithms for combining the effects of radiation and hydrodynamics, which will have a wide application in astronomy, atmospheric science and engineering and constraints on the processes of planet formation. The anticipated outcome of the project is to pinpoint the regions where ....Formation and evolution of planetary systems. This project aims to develop computer simulation methods and mathematical modelling to help solve the mystery of how planets form. The project should also produce world-first algorithms for combining the effects of radiation and hydrodynamics, which will have a wide application in astronomy, atmospheric science and engineering and constraints on the processes of planet formation. The anticipated outcome of the project is to pinpoint the regions where the dust grains grow to form the building blocks of planets.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100437
Funder
Australian Research Council
Funding Amount
$338,774.00
Summary
Advanced technologies for next generation gravitational wave detectors. This project aims to investigate a novel scheme that uses signals present in interferometers to directly control and stabilise the shapes of mirrors to atomic scale precision. The discovery of gravitational waves from colliding black holes and neutron stars was made possible by the development of large-scale, high-laser-power interferometers. The project builds on experience with current detectors and aims to develop techniq ....Advanced technologies for next generation gravitational wave detectors. This project aims to investigate a novel scheme that uses signals present in interferometers to directly control and stabilise the shapes of mirrors to atomic scale precision. The discovery of gravitational waves from colliding black holes and neutron stars was made possible by the development of large-scale, high-laser-power interferometers. The project builds on experience with current detectors and aims to develop techniques that will provide the next leap in sensitivity by improving control of the quantum state of light. The project will also test a new technique called white light resonance, which has the revolutionary capability of increasing sensitivity over a broad frequency range. The project will help maintain Australia’s significant impact on the worldwide effort to harness gravitational waves.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101738
Funder
Australian Research Council
Funding Amount
$345,000.00
Summary
Discovering the most extreme pulsars with the next generation radio surveys. Finding radio pulsars has always been an extremely rewarding challenge and has led to Nobel Prize winning science. We are now entering a new era of radio astronomy and have new game changers, sensitive, wide-field-of-view imaging telescopes and massive compute resources, to search for extreme pulsars. Such pulsars, including pulsar-blackhole systems and sub-millisecond pulsars, cannot be found with traditional pulsar su ....Discovering the most extreme pulsars with the next generation radio surveys. Finding radio pulsars has always been an extremely rewarding challenge and has led to Nobel Prize winning science. We are now entering a new era of radio astronomy and have new game changers, sensitive, wide-field-of-view imaging telescopes and massive compute resources, to search for extreme pulsars. Such pulsars, including pulsar-blackhole systems and sub-millisecond pulsars, cannot be found with traditional pulsar surveys, but provide us unique laboratories to test gravity theories at ultra-strong gravitational fields and probe the state of matter at supra-nuclear densities. In this project I will leverage the Australian Square Kilometre Array Pathfinder (ASKAP) to discover the most extreme pulsars in deep all-sky continuum surveys.Read moreRead less