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“Beacons in the Night” unveiling how galaxies light up dark matter. How dark matter influences the formation and evolution of galaxies is to this day an outstanding question in astrophysics. To answer it, world-class facilities and a unique combination of observations and theory are required. This DP team, a world-class team of observers and theorists, will tackle this question by leveraging on two multi-million dollar projects: the MAGPI galaxy survey and the hydrodynamical simulations suite EA ....“Beacons in the Night” unveiling how galaxies light up dark matter. How dark matter influences the formation and evolution of galaxies is to this day an outstanding question in astrophysics. To answer it, world-class facilities and a unique combination of observations and theory are required. This DP team, a world-class team of observers and theorists, will tackle this question by leveraging on two multi-million dollar projects: the MAGPI galaxy survey and the hydrodynamical simulations suite EAGLE-XL. MAGPI will deliver exquisite kinematics for hundreds of galaxies in the middle ages of the Universe, providing a view to the effect of dark matter on galaxies at this critical time, while EAGLE-XL represents the technological frontier in simulations and provides the best interpretative framework for MAGPI.Read moreRead less
The next wave of asteroseismic discovery using NASA’s TESS mission. This project aims to make advances in astrophysics by capitalising on NASA’s upcoming Transiting Exoplanet Survey Satellite (TESS) mission and recent breakthroughs in artificial intelligence. Through an innovative approach to analyse big datasets, the project expects to generate new knowledge in the key areas of planet formation, stellar structure, and the Galaxy’s evolution. Outcomes include strong international links to leadin ....The next wave of asteroseismic discovery using NASA’s TESS mission. This project aims to make advances in astrophysics by capitalising on NASA’s upcoming Transiting Exoplanet Survey Satellite (TESS) mission and recent breakthroughs in artificial intelligence. Through an innovative approach to analyse big datasets, the project expects to generate new knowledge in the key areas of planet formation, stellar structure, and the Galaxy’s evolution. Outcomes include strong international links to leading institutions and enhanced capacity for Australia to be part of cutting-edge space exploration. The methods and skills developed by the project should provide significant benefits to other data-driven sciences and help build smarter business models and improved decision making in industry and government in our increasingly data-dependent economy.Read moreRead less
The pathway to planets: formation of protoplanetary discs. This project aims to expand our knowledge of how planetary systems are born. Observations are bringing new insight into the structure of discs of dusty gas orbiting young stars, but not in sufficient detail to understand how planets form within them. This project aims to link the structure of discs to the well-characterised interstellar cloud cores that collapse to form star-disc systems. The project aspires to use innovative techniques ....The pathway to planets: formation of protoplanetary discs. This project aims to expand our knowledge of how planetary systems are born. Observations are bringing new insight into the structure of discs of dusty gas orbiting young stars, but not in sufficient detail to understand how planets form within them. This project aims to link the structure of discs to the well-characterised interstellar cloud cores that collapse to form star-disc systems. The project aspires to use innovative techniques to enable the rapid collapse calculations needed to map core properties to disc structure. Expected outcomes include knowledge of the disc structures critical to interpreting observations of forming planetary systems. The benefit will be guidance to the theory needed to explain the incredible variety of planetary systems we see today.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: LE180100165
Funder
Australian Research Council
Funding Amount
$792,859.00
Summary
Veloce Verde+Azzuro - Tripling the Power of Australia's Planet Foundry. This project aims to better understand humanity’s place in the Universe, including questions such as whether we are alone or if our home in the Solar System is unique or common. This project will enable new observations using a revolutionary Australian facility, Veloce Verde+Azzuro. Moving beyond discovering habitable planets around dim red stars, it will enable science on the properties and system architectures of planets o ....Veloce Verde+Azzuro - Tripling the Power of Australia's Planet Foundry. This project aims to better understand humanity’s place in the Universe, including questions such as whether we are alone or if our home in the Solar System is unique or common. This project will enable new observations using a revolutionary Australian facility, Veloce Verde+Azzuro. Moving beyond discovering habitable planets around dim red stars, it will enable science on the properties and system architectures of planets orbiting stars like the Sun. It will deliver a ten-fold increase in collecting power for Sun-like stars, providing understanding of how exoplanetary systems, and our Solar System, were formed.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100201
Funder
Australian Research Council
Funding Amount
$530,000.00
Summary
A major upgrade to the Australia Telescope Compact Array. This project aims to upgrade the $150m CSIRO Australia Telescope Compact Array ("the telescope"), by replacing the signal processing electronics and doubling the bandwidth. This will significantly enhance the performance of the telescope, enabling more ambitious science by the 450 researchers and students who use it each year. For example, it will enable the telescope to study radio counterparts to Gravitational Wave sources, and it will ....A major upgrade to the Australia Telescope Compact Array. This project aims to upgrade the $150m CSIRO Australia Telescope Compact Array ("the telescope"), by replacing the signal processing electronics and doubling the bandwidth. This will significantly enhance the performance of the telescope, enabling more ambitious science by the 450 researchers and students who use it each year. For example, it will enable the telescope to study radio counterparts to Gravitational Wave sources, and it will enable it to make detailed observations of initial discoveries made with the Australian Square Kilometre Array Pathfinder and other Australian telescopes. In short, it will enable Australian researchers to do more ambitious research, and make more discoveries, across broad areas of astrophysics.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
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
Continuous Reaction Networks that Model Chemical Evolution of RNA. This Project aims to develop experimental models for chemical evolution that may have happened on the early Earth and which were important to the emergence of life. This Project expects to uncover synthetic pathways for ribonucleotide production using a combination of ionizing radiation and dry-wet cycles. Expected outcomes include an increased understanding of the range of physical and chemical parameters that will allow for rib ....Continuous Reaction Networks that Model Chemical Evolution of RNA. This Project aims to develop experimental models for chemical evolution that may have happened on the early Earth and which were important to the emergence of life. This Project expects to uncover synthetic pathways for ribonucleotide production using a combination of ionizing radiation and dry-wet cycles. Expected outcomes include an increased understanding of the range of physical and chemical parameters that will allow for ribonucleotide production to occur under the proposed geochemical settings. The knowledge gained in this Project will benefit the understanding of the chemical evolution of complex chemical mixtures relevant to early Earth environments and provide new mechanisms for how ribonucleotides could have arisen abiotically.Read moreRead less