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Discovery Early Career Researcher Award - Grant ID: DE240100150
Funder
Australian Research Council
Funding Amount
$459,000.00
Summary
How galactic mergers and their stellar survivors shaped our Milky Way. This project aims to investigate the role of mergers with smaller galaxies in shaping the Milky Way by developing tools to identify stellar survivors of mergers. This project expects to produce an all-sky map of stellar survivors based on the largest search within Australian and international survey data and perform innovative comparisons with simulations to constrain the role of mergers. Expected outcomes are aligned with th ....How galactic mergers and their stellar survivors shaped our Milky Way. This project aims to investigate the role of mergers with smaller galaxies in shaping the Milky Way by developing tools to identify stellar survivors of mergers. This project expects to produce an all-sky map of stellar survivors based on the largest search within Australian and international survey data and perform innovative comparisons with simulations to constrain the role of mergers. Expected outcomes are aligned with the decadal plan for Australian astronomy and can open new avenues for global astronomy and contracts for upcoming billion-dollar surveys. The project should cement Australia’s role as a leader in a new era of galactic exploration and provide benefits beyond astronomy by training Australians to assess complex big data.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101069
Funder
Australian Research Council
Funding Amount
$433,219.00
Summary
Awakening giants in galaxies: Using stars to probe supermassive black holes. This project aims to understand the unexplored population of non-active or quiescent supermassive black holes (SMBHs) using tidal disruption events - the multi-wavelength outburst resulting from a star being ripped apart by the tidal forces of the SMBH. This project will increase our understanding of the transient and accretion properties of SMBHs in a broad range of galaxies, while the expected outcomes include novel t ....Awakening giants in galaxies: Using stars to probe supermassive black holes. This project aims to understand the unexplored population of non-active or quiescent supermassive black holes (SMBHs) using tidal disruption events - the multi-wavelength outburst resulting from a star being ripped apart by the tidal forces of the SMBH. This project will increase our understanding of the transient and accretion properties of SMBHs in a broad range of galaxies, while the expected outcomes include novel techniques for distinguishing different types of extreme SMBH emission and characterisation of the environments where these extreme transient events occur. These outcomes will facilitate the identification of transient SMBH events and enhance the scientific return of the next generation of international optical surveys.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100055
Funder
Australian Research Council
Funding Amount
$445,437.00
Summary
Illuminating the dark Universe with explosive astrophysical events. Explosive astrophysical events are critical to understand what the Universe is made of and its physics. This project aims to single out the most exciting exploding stars and extreme events out of the millions detected each night at the world’s largest optical telescope. It will magnify Australian leadership and optimise investment in astronomical facilities by obtaining unique information before these events fade forever. Expect ....Illuminating the dark Universe with explosive astrophysical events. Explosive astrophysical events are critical to understand what the Universe is made of and its physics. This project aims to single out the most exciting exploding stars and extreme events out of the millions detected each night at the world’s largest optical telescope. It will magnify Australian leadership and optimise investment in astronomical facilities by obtaining unique information before these events fade forever. Expected outcomes include improved knowledge on the nature of exploding stars and the discovery of new events and physical processes. It will benefit the Australian community at large by training young Australians in data-intensive technologies required to lead ground-breaking research and advance our innovative economy.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100816
Funder
Australian Research Council
Funding Amount
$444,000.00
Summary
Probing dark energy with the largest 3D Map of the Universe. Dark Energy is one of the most profound mysteries of modern physics. It makes up about 70 percent of the Universe, but no compelling theory can explain its nature. This project aims to measure the properties of Dark Energy with unprecedented accuracy: an order of magnitude better than the state of the art. It aims to accomplish this by extracting information from the largest 3D map of the cosmos, built with the optical spectra of 35 mi ....Probing dark energy with the largest 3D Map of the Universe. Dark Energy is one of the most profound mysteries of modern physics. It makes up about 70 percent of the Universe, but no compelling theory can explain its nature. This project aims to measure the properties of Dark Energy with unprecedented accuracy: an order of magnitude better than the state of the art. It aims to accomplish this by extracting information from the largest 3D map of the cosmos, built with the optical spectra of 35 million galaxies, observed by the Dark Energy Spectroscopic Instrument. This project will foster Australia's historic leadership and investments in galaxy surveys via unique international partnerships, and produce cutting-edge tools for big data analyses with important applications in a wide range of industries.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100136
Funder
Australian Research Council
Funding Amount
$441,700.00
Summary
Galactic Outflows: Pushing the Distance Frontiers. This project aims to push the frontiers of our knowledge of galactic outflows: a key physical process shaping galaxy formation and evolution. Using cutting-edge facilities including the new, high-profile James Webb Space Telescope, this project expects to build the first holistic picture of outflows in the distant past, when present-day galaxies were still taking shape. Expected outcomes include a novel framework for measuring outflow properties ....Galactic Outflows: Pushing the Distance Frontiers. This project aims to push the frontiers of our knowledge of galactic outflows: a key physical process shaping galaxy formation and evolution. Using cutting-edge facilities including the new, high-profile James Webb Space Telescope, this project expects to build the first holistic picture of outflows in the distant past, when present-day galaxies were still taking shape. Expected outcomes include a novel framework for measuring outflow properties, and new understanding of the physics of distant outflows. This research is expected to provide strong benefits by enhancing the legacy of Australia’s $122M partnership with the European Southern Observatory and placing Australia at the forefront of the James Webb Space Telescope revolution.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100206
Funder
Australian Research Council
Funding Amount
$403,000.00
Summary
Probing ultralight bosons with black holes and gravitational waves. This project aims to search for gravitational waves from ultralight boson clouds around black holes and to investigate the boson properties. It expects to generate new knowledge on currently undiscovered particles by combining cutting-edge theories and innovative signal-processing techniques. These particles are predicted to solve problems in particle and high-energy physics and are compelling dark matter candidates. Expected ou ....Probing ultralight bosons with black holes and gravitational waves. This project aims to search for gravitational waves from ultralight boson clouds around black holes and to investigate the boson properties. It expects to generate new knowledge on currently undiscovered particles by combining cutting-edge theories and innovative signal-processing techniques. These particles are predicted to solve problems in particle and high-energy physics and are compelling dark matter candidates. Expected outcomes include high-profile constraints on the particle properties and potential detection of new particles, new data-analysis techniques, and significantly enhanced capacity to build international and interdisciplinary collaborations. These should bring significant benefits to fundamental physics and cosmology.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240101377
Funder
Australian Research Council
Funding Amount
$381,237.00
Summary
Measuring the glow from our Cosmic Dawn. The Cosmic Dawn is one of the last unexplored periods of the history of the Universe. The faint glow of intergalactic hydrogen during the birth of the first galaxies can shed light on the formation of structure in the Universe. Many are seeking the first detection, notably teams in Australia, the USA, and the Netherlands. This project proposes to synthesise the knowledge across these communities for the first time, resulting in a new, cross-validated anal ....Measuring the glow from our Cosmic Dawn. The Cosmic Dawn is one of the last unexplored periods of the history of the Universe. The faint glow of intergalactic hydrogen during the birth of the first galaxies can shed light on the formation of structure in the Universe. Many are seeking the first detection, notably teams in Australia, the USA, and the Netherlands. This project proposes to synthesise the knowledge across these communities for the first time, resulting in a new, cross-validated analysis utilising worldwide expertise, for the benefit of Australia's Murchison Widefield Array. This collaborative approach will discover the best methods for precision analysis of the early Universe, and definitively embed Australia as the global leader in the search for our Cosmic Dawn.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100183
Funder
Australian Research Council
Funding Amount
$377,429.00
Summary
Understanding the birth of new elements by observing dying stars. Almost everything around us is made up of elements that were created inside stars. This project aims to understand the origin of the elements by studying newly created material ejected by Sun-like stars during one of the final stages of their lives. This project expects to generate new knowledge in the field of stellar evolution by using state-of-the-art telescopes to measure the elements and isotopes produced by these stars and c ....Understanding the birth of new elements by observing dying stars. Almost everything around us is made up of elements that were created inside stars. This project aims to understand the origin of the elements by studying newly created material ejected by Sun-like stars during one of the final stages of their lives. This project expects to generate new knowledge in the field of stellar evolution by using state-of-the-art telescopes to measure the elements and isotopes produced by these stars and comparing them with theoretical model predictions. Expected outcomes include a better understanding of element creation, the chemical enrichment of galaxies, and the first mass estimates for intermediate-mass stars. This should provide significant benefits by addressing a key outstanding question in astronomy.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101035
Funder
Australian Research Council
Funding Amount
$368,818.00
Summary
Gravitational wave detectors for observing the Cosmic Dawn. This project aims to build upon Australia’s already pioneering research into the workings of the universe by addressing challenges facing future gravitational wave detectors. It will develop and utilise advanced new numerical models to generate new knowledge on large-scale precision interferometry and contribute towards the design of future detectors that are essential for gravitational wave astronomy to thrive. Expected outcomes are ne ....Gravitational wave detectors for observing the Cosmic Dawn. This project aims to build upon Australia’s already pioneering research into the workings of the universe by addressing challenges facing future gravitational wave detectors. It will develop and utilise advanced new numerical models to generate new knowledge on large-scale precision interferometry and contribute towards the design of future detectors that are essential for gravitational wave astronomy to thrive. Expected outcomes are new optimised designs for detectors and an array of innovative new open-source numerical models for exploring new designs of quantum optics experiments. This will benefit both Australian and international research teams in the global effort to realise the third generation of gravitational wave detectors.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100433
Funder
Australian Research Council
Funding Amount
$390,627.00
Summary
Origins and implications of cosmic explosions . This project aims to solve the origin of Fast Radio Bursts (FRBs) by conducting a study of a large sample (>100) of localised bursts detected with a new coherent FRB detection system called CRACO deployed at the Australia Square Kilometre Array Pathfinder (ASKAP). Such a rich sample will enable novel studies of the structure of the Universe. The powerful and sensitive CRACO system will also search for transients that last for hundreds of millisecon ....Origins and implications of cosmic explosions . This project aims to solve the origin of Fast Radio Bursts (FRBs) by conducting a study of a large sample (>100) of localised bursts detected with a new coherent FRB detection system called CRACO deployed at the Australia Square Kilometre Array Pathfinder (ASKAP). Such a rich sample will enable novel studies of the structure of the Universe. The powerful and sensitive CRACO system will also search for transients that last for hundreds of milliseconds, exploring new types of astrophysical phenomena that give insight into the Universe's extremes. These discoveries will have a significant impact on science, establishing Australia as a key player in the international FRB community.
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