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New Dimensions in Radio Astronomy: Mining Sparse Datasets with the Australian Square Kilometre Array Pathfinder. Radio astronomy is entering a new era, driven by technological advances that make rapid surveys of the sky possible. As leaders of three major surveys for the Australian Square Kilometre Array Pathfinder (ASKAP) telescope, we will explore three new dimensions of astronomy: searching for transient sources, detecting faint galaxies and investigating cosmic magnetism. The project will pu ....New Dimensions in Radio Astronomy: Mining Sparse Datasets with the Australian Square Kilometre Array Pathfinder. Radio astronomy is entering a new era, driven by technological advances that make rapid surveys of the sky possible. As leaders of three major surveys for the Australian Square Kilometre Array Pathfinder (ASKAP) telescope, we will explore three new dimensions of astronomy: searching for transient sources, detecting faint galaxies and investigating cosmic magnetism. The project will put Australian astronomers at the forefront of international research. In addition to novel scientific results we will produce data resources and software that will be critical for future Square Kilometre Array projects. These will be available online to amateur astronomers and the general public. We will train the next generation of astronomers with the skills required to make breakthrough discoveries.Read moreRead less
Probing dark matter through the small scale structure of the universe. This project aims to discover clues to the nature of dark matter buried in small-scale structures. Although observational probes reliably constrain these systems, theoretical progress is hampered by difficulties disentangling the complex baryonic physics from the micro-physics of the dark matter particle in shaping the structure of low-mass galaxies. The project will tackle this problem using sophisticated numerical simulatio ....Probing dark matter through the small scale structure of the universe. This project aims to discover clues to the nature of dark matter buried in small-scale structures. Although observational probes reliably constrain these systems, theoretical progress is hampered by difficulties disentangling the complex baryonic physics from the micro-physics of the dark matter particle in shaping the structure of low-mass galaxies. The project will tackle this problem using sophisticated numerical simulations which separate these effects, allowing them to be isolated. The results are expected to show how low-mass galaxy formed, and to have important implications for modelling dark matter annihilation and for interpreting data from forthcoming surveys.Read moreRead less
Unveiling the haloes of Andromeda and the Milky Way. This project aims to understand galaxy formation and the astrophysical properties of dark matter. Continual merging with smaller systems powers the development of large galaxies. The ghostly remnants of these cannibalised satellites encode the build-up of mass in a galaxy and trace the underlying gravitational field. This project will use astronomical imaging technology to study ultra-faint stellar streams in the outskirts of our Milky Way and ....Unveiling the haloes of Andromeda and the Milky Way. This project aims to understand galaxy formation and the astrophysical properties of dark matter. Continual merging with smaller systems powers the development of large galaxies. The ghostly remnants of these cannibalised satellites encode the build-up of mass in a galaxy and trace the underlying gravitational field. This project will use astronomical imaging technology to study ultra-faint stellar streams in the outskirts of our Milky Way and its twin sister Andromeda, revealing their assembly histories and the precise properties of their dark matter haloes. These quantities are fundamental experimental benchmarks for testing modern cosmological models.Read moreRead less
eXtending the GLEAM view of the Universe. This project will explore the entire radio sky visible to the future Square Kilometre Array ten times more deeply than before, fully characterising the life cycles of active galactic nuclei and finding previously-undetected supernova remnants in the Galactic Plane. The resulting survey will be used for a plethora of science, such as studies of galaxy clusters, cosmic ray tomography of the Milky Way, and measuring the magnetic fields of radio galaxy lobes ....eXtending the GLEAM view of the Universe. This project will explore the entire radio sky visible to the future Square Kilometre Array ten times more deeply than before, fully characterising the life cycles of active galactic nuclei and finding previously-undetected supernova remnants in the Galactic Plane. The resulting survey will be used for a plethora of science, such as studies of galaxy clusters, cosmic ray tomography of the Milky Way, and measuring the magnetic fields of radio galaxy lobes. It is a critical step toward the Square Kilometre Array.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL220100191
Funder
Australian Research Council
Funding Amount
$2,609,122.00
Summary
Unveiling the mass of the Universe: stars, gas, plasma and dark matter. Using unique Australian-built fibre-positioning technologies, the Fellowship will measure the distances to 2 million galaxies, transforming our understanding of dark matter on the scales of galaxies, galaxy groups, and filaments – the largest structures that exist. There are two specific goals: (i) to test precise predictions of the leading cold dark matter model by constructing dark-matter halo catalogues based on the motio ....Unveiling the mass of the Universe: stars, gas, plasma and dark matter. Using unique Australian-built fibre-positioning technologies, the Fellowship will measure the distances to 2 million galaxies, transforming our understanding of dark matter on the scales of galaxies, galaxy groups, and filaments – the largest structures that exist. There are two specific goals: (i) to test precise predictions of the leading cold dark matter model by constructing dark-matter halo catalogues based on the motions of galaxies measured to unprecedented accuracy; and (ii) to solve the long-standing "missing mass" problem by measuring the extent of the plasma, neutral gas, and stellar contents within these halos. Both programs will capitalise on our strategic engagement with the European Southern Observatory.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150100618
Funder
Australian Research Council
Funding Amount
$354,000.00
Summary
Gas in the Cosmic Web: feeding and feedback of galaxies. This project aims to understand the complete cycle of gas in galaxies: from the process of feeding galaxies, going through star formation, to the process of outflowing gas from galaxies. This requires a full physical description of the inflow of gas from filaments going through the halo until reaching galaxies, the process of star formation in a multi-phase gas medium, and the effect energetic events have on the gas content of galaxies. Th ....Gas in the Cosmic Web: feeding and feedback of galaxies. This project aims to understand the complete cycle of gas in galaxies: from the process of feeding galaxies, going through star formation, to the process of outflowing gas from galaxies. This requires a full physical description of the inflow of gas from filaments going through the halo until reaching galaxies, the process of star formation in a multi-phase gas medium, and the effect energetic events have on the gas content of galaxies. This project in the field of extragalactic astrophysics is designed to complement major observational efforts in Australia, such as the Square Kilometre Array and its Pathfinder, as it will provide simulations with full physical descriptions of the neutral gas in the Universe.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 evolution of mass and energy over the past 13 billion years. The universe has slowly transformed atomic material into a range of structures from planets, stars, galaxies, clusters and filaments. In the process the universe has generated energy at almost all wavelengths. This project will build a model to explain the evolution of mass, energy and structure in the universe and will test the model using the latest data.