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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
Beyond appearance: revealing the physics of galaxy transformation. This project aims to reveal the physical origin of the large variety of galaxies in the universe by utilising multi-wavelength observations of nearby galaxies combined with advanced data analysis techniques and cutting-edge numerical simulations. The project expects to generate new knowledge in the area of astrophysics by providing a physically-motivated foundation to the subjective and qualitative taxonomic scheme generally used ....Beyond appearance: revealing the physics of galaxy transformation. This project aims to reveal the physical origin of the large variety of galaxies in the universe by utilising multi-wavelength observations of nearby galaxies combined with advanced data analysis techniques and cutting-edge numerical simulations. The project expects to generate new knowledge in the area of astrophysics by providing a physically-motivated foundation to the subjective and qualitative taxonomic scheme generally used to understand how galaxies, and ultimately stars and planets, formed and evolve. 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
Weighing the Giants: Using Galaxy Clusters to understand Dark Energy. This project seeks to reveal the nature of dark energy and thereby explain what is causing expansion of the Universe to accelerate. The project will develop new deep machine learning techniques to weigh galaxy clusters, and apply them to data from the SPT-3G experiment at the South Pole. By comparing theoretical predictions to the observed numbers and masses of galaxy clusters, the project will help determine whether the accel ....Weighing the Giants: Using Galaxy Clusters to understand Dark Energy. This project seeks to reveal the nature of dark energy and thereby explain what is causing expansion of the Universe to accelerate. The project will develop new deep machine learning techniques to weigh galaxy clusters, and apply them to data from the SPT-3G experiment at the South Pole. By comparing theoretical predictions to the observed numbers and masses of galaxy clusters, the project will help determine whether the acceleration is due to dark energy or a breakdown in general relativity. The data science training received by students and researchers on the project will also contribute to a highly skilled STEM workforce for Australia.
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Unveiling the first billion years: enabling epoch of reionisation science. This project aims to deliver detections and exploration of the Epoch of Reionisation (EoR) through observation of the 21 cm hydrogen emission line from gas in the first billion years of the Universe. The EoR and Cosmic Dawn mark the two remaining unobserved periods in the history of the Universe. Together, they are witness to the formation, birth and illumination of the first stars, galaxies and x-ray sources, and the con ....Unveiling the first billion years: enabling epoch of reionisation science. This project aims to deliver detections and exploration of the Epoch of Reionisation (EoR) through observation of the 21 cm hydrogen emission line from gas in the first billion years of the Universe. The EoR and Cosmic Dawn mark the two remaining unobserved periods in the history of the Universe. Together, they are witness to the formation, birth and illumination of the first stars, galaxies and x-ray sources, and the consequent transformation of the intergalactic medium from a cold, neutral fog of hydrogen, to a heated, ionised canvas for the luminous Universe. The 21cm neutral hydrogen radio signal maps the astrophysics and cosmology of the first billion years, providing a direct tracer of their evolution and spatial distribution. The project will deliver advances in early Universe physics by circumventing limitations of current experiments, and will deliver lasting scientific and technological breakthroughs.Read moreRead less
Wobbling stars reveal their hidden companions. This project aims to measure the wobble in the position of distant stars that is caused by massive objects, using telescopes in space. This project expects to generate new knowledge on how binary stars, exoplanets, and stellar mass black holes are formed. Expected outcomes of this project include tight constraints on binary star models, new discoveries of neutron stars and black holes that are a few times more massive than the Sun, and samples of st ....Wobbling stars reveal their hidden companions. This project aims to measure the wobble in the position of distant stars that is caused by massive objects, using telescopes in space. This project expects to generate new knowledge on how binary stars, exoplanets, and stellar mass black holes are formed. Expected outcomes of this project include tight constraints on binary star models, new discoveries of neutron stars and black holes that are a few times more massive than the Sun, and samples of stars that do, and do not, host exoplanets. This should provide significant benefits including a catalogue of companion properties for billions of sources, new understanding of how stars die, as well as the first control sample of stars without planets to help understand how and why planets form.Read moreRead less
Equipping VIKiNG: mid-infrared technology for exoplanet characterisation. This project aims to develop thermal infrared technologies for the Very large telescope interferometer Infrared Kernel-NullinG instrument (VIKiNG), making it the most capable direct exoplanet detection instrument on any existing, or under construction, facility. Australia is currently world leading in innovative photonics technologies, and these are currently the limiting factor in producing a manufacturable design for VIK ....Equipping VIKiNG: mid-infrared technology for exoplanet characterisation. This project aims to develop thermal infrared technologies for the Very large telescope interferometer Infrared Kernel-NullinG instrument (VIKiNG), making it the most capable direct exoplanet detection instrument on any existing, or under construction, facility. Australia is currently world leading in innovative photonics technologies, and these are currently the limiting factor in producing a manufacturable design for VIKiNG. This project provides a clear pathway for laboratory development of high-efficiency, active mid-infrared photonic circuits in the thermal infrared. Beyond benefits to astronomy, these circuits are the first step in developing remote molecule detectors for environmental monitoring and security.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