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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Novel 2-photon atom manipulation for ultra-nanoscale processing of diamond. There is intense interest in exploiting diamond's remarkable properties in many fields of science and technology, but fabricating and processing devices remains a major challenge. This project will build on previous work, using a recently discovered novel laser-induced surface phenomenon that enables, for the first time for any material, the exciting prospect of using light to manipulate surface atoms with atomic precis ....Novel 2-photon atom manipulation for ultra-nanoscale processing of diamond. There is intense interest in exploiting diamond's remarkable properties in many fields of science and technology, but fabricating and processing devices remains a major challenge. This project will build on previous work, using a recently discovered novel laser-induced surface phenomenon that enables, for the first time for any material, the exciting prospect of using light to manipulate surface atoms with atomic precision. This project aims to elucidate the mechanisms underpinning the optical interaction to reveal its full potential and use it to address key problems in diamond nano-device fabrication that lie beyond the reach of current techniques. It is expected that the outcomes will directly enhance Australia's current strengths in diamond-based quantum and photonic technologies.Read moreRead less
Pinpointing the hosts of Fast Radio Bursts with UTMOST-2D. This project proposes to localise a sample of detected ‘fast radio bursts’ to their host galaxies (or local progenitors) for the first time. ‘Fast radio bursts’ are impulsive bursts of radio energy, with characteristics consistent with an origin billions of light-years from Earth. If the source of the bursts can be pinpointed, they would offer a unique tool to study the tenuous, otherwise nearly invisible plasma that permeates the interg ....Pinpointing the hosts of Fast Radio Bursts with UTMOST-2D. This project proposes to localise a sample of detected ‘fast radio bursts’ to their host galaxies (or local progenitors) for the first time. ‘Fast radio bursts’ are impulsive bursts of radio energy, with characteristics consistent with an origin billions of light-years from Earth. If the source of the bursts can be pinpointed, they would offer a unique tool to study the tenuous, otherwise nearly invisible plasma that permeates the intergalactic medium. They could also be used as cosmic rulers to measure the expansion history of the Universe. To date, no burst has been associated with a host galaxy at a known distance, and some researchers maintain that fast radio bursts originate from more nearby sources, potentially even within our own Galaxy. The project plans to explore this hypothesis.Read moreRead less
Illuminating the cosmic web with Fast Radio Bursts. This project aims to establish the use of millisecond-duration Fast Radio Bursts as a wholly new means to map out the distribution of matter in the Universe. This project expects to localise 100s of bursts using novel infrastructure deployed on Australia's largest radio telescopes. Expected outcomes include an understanding of the processes that shape both the large-scale structures of the Universe, and the extreme conditions that exist at the ....Illuminating the cosmic web with Fast Radio Bursts. This project aims to establish the use of millisecond-duration Fast Radio Bursts as a wholly new means to map out the distribution of matter in the Universe. This project expects to localise 100s of bursts using novel infrastructure deployed on Australia's largest radio telescopes. Expected outcomes include an understanding of the processes that shape both the large-scale structures of the Universe, and the extreme conditions that exist at the sites of Fast Radio Bursts. This should provide significant benefits to our fundamental knowledge of the Universe, inspire students into careers in science, technology, engineering and mathematics, and develop signal processing techniques of application to both the Square Kilometre Array and industry.Read moreRead less
Enlightening single rare-earth atoms in scanning-tunnelling microscopy. This project aims to create a tool to systematically engineer optical properties of emitters in solids by understanding and manipulating materials atom by atom. The tool – an optically enhanced scanning tunnelling microscope – is expected to drive future developments in optical technologies. The project expects to deliver an atomic-scale understanding of rare-earth sites optimised for sensing and coherence. The expected outc ....Enlightening single rare-earth atoms in scanning-tunnelling microscopy. This project aims to create a tool to systematically engineer optical properties of emitters in solids by understanding and manipulating materials atom by atom. The tool – an optically enhanced scanning tunnelling microscope – is expected to drive future developments in optical technologies. The project expects to deliver an atomic-scale understanding of rare-earth sites optimised for sensing and coherence. The expected outcomes include highly developed theoretical insights into solid-state emitters and how to control their interactions with light and other fields. The expected benefit based on the ability to engineer optimised emitters for optical sensors and quantum technologies will transform material science from exploration to design.Read moreRead less
Understanding the enigma of the most energetic particles in the Universe. By combining an innovative Unmanned Aerial Vehicle (UAV)-based calibration technique with the unparalleled sensitivity of future gamma-ray and radio telescope arrays, this project will study astronomical particle accelerators and Dark Matter with unprecedented accuracy. This will afford us a unique view of the Universe' most energetic processes and allow us to study the laws of physics inaccessible to us in the lab. In the ....Understanding the enigma of the most energetic particles in the Universe. By combining an innovative Unmanned Aerial Vehicle (UAV)-based calibration technique with the unparalleled sensitivity of future gamma-ray and radio telescope arrays, this project will study astronomical particle accelerators and Dark Matter with unprecedented accuracy. This will afford us a unique view of the Universe' most energetic processes and allow us to study the laws of physics inaccessible to us in the lab. In the context of interdisciplinary research, the UAV innovation created will also be leveraged against key applications of remote sensing. With these two goals, this project will demonstrate the capabilities of novel Australian technology whilst providing Australia with a unique science use-case in high-energy astrophysics.Read moreRead less