A fast readout for new physics discovery at the Large Hadron Collider. This project aims to explore fundamental physics by developing new technologies to exploit data readout and analysis techniques. With the discovery of the Higgs boson, the focus of high energy physics has progressed to answering fundamental questions of what forces and particles may lie beyond the Standard Model of particle physics. The upgraded Large Hadron Collider provides a unique environment to discover new physics proce ....A fast readout for new physics discovery at the Large Hadron Collider. This project aims to explore fundamental physics by developing new technologies to exploit data readout and analysis techniques. With the discovery of the Higgs boson, the focus of high energy physics has progressed to answering fundamental questions of what forces and particles may lie beyond the Standard Model of particle physics. The upgraded Large Hadron Collider provides a unique environment to discover new physics processes by enabling searches at the highest energies and masses ever achieved to directly produce new particles. The project expects to enhance fundamental physics and interdisciplinary research in industry and academia.Read moreRead less
A comprehensive approach to dark matter searches: the Cherenkov Telescope Array, IceCube and the Large Hadron Collider. Following the recent discovery of the Higgs boson, the greatest outstanding mystery in physics, it is now time to identify the nature of the dark matter that fills much of our Universe. This project aims to invent new data mining techniques to test the viability of a wide class of theoretical dark matter models, using an extensive range of particle physics and astrophysics data ....A comprehensive approach to dark matter searches: the Cherenkov Telescope Array, IceCube and the Large Hadron Collider. Following the recent discovery of the Higgs boson, the greatest outstanding mystery in physics, it is now time to identify the nature of the dark matter that fills much of our Universe. This project aims to invent new data mining techniques to test the viability of a wide class of theoretical dark matter models, using an extensive range of particle physics and astrophysics data. It will use these models to help design the next generation of dark matter searches in gamma ray and neutrino astronomy, using the Large Hadron Collider. This project aims to put Australia at the forefront of international particle astrophysics research and potential new discoveries will change the future direction of international particle research.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100076
Funder
Australian Research Council
Funding Amount
$150,068.00
Summary
Australian Participation in the Belle II Experiment. Australian participation in the Belle II experiment: This project will provide membership for Australian scientists of one of the key contemporary particle physics experiments, the Belle II experiment in Japan, and contribute to the purchase and installation of equipment for the Japanese facility. The Belle II experiment aims to search for a deeper theory of nature which will add significantly to our ability to answer questions such as why the ....Australian Participation in the Belle II Experiment. Australian participation in the Belle II experiment: This project will provide membership for Australian scientists of one of the key contemporary particle physics experiments, the Belle II experiment in Japan, and contribute to the purchase and installation of equipment for the Japanese facility. The Belle II experiment aims to search for a deeper theory of nature which will add significantly to our ability to answer questions such as why there is a preponderance of matter over antimatter in the Universe, and what is the nature of the dark matter which pervades it. This project will allow Australian scientists to pursue these questions in the coming years, with the additional benefit of increasing Australia's research profile in fundamental physics and its engagement with basic science in the Asia-Pacific region.Read moreRead less
Probing the experimental frontier of particle physics with high-precision and high-energy collisions. Analysis of data from the high-energy collisions at the Large Hadron Collider, and B-physics observables, will provide a new precision by which to interrogate our picture of the Universe. The interplay between these two novel and complementary approaches will unveil the fundamental nature of the particles that make up all known matter. Technological advances in high precision data analysis, and ....Probing the experimental frontier of particle physics with high-precision and high-energy collisions. Analysis of data from the high-energy collisions at the Large Hadron Collider, and B-physics observables, will provide a new precision by which to interrogate our picture of the Universe. The interplay between these two novel and complementary approaches will unveil the fundamental nature of the particles that make up all known matter. Technological advances in high precision data analysis, and experimental data readout, will result in significant advances in the global knowledge of particle detector performance and operation. New techniques in data analysis will arise from this work. In going beyond the Standard Model and discovering extensions to the theory, the ultimate outcome of this project will define new directions for the field.Read moreRead less
The top quark: a portal to new physics in particle colliders. This project aims to address fundamental questions of particle physics by studying the top quark, the most elementary particle known. The project will generate new knowledge about the top quark and the recently discovered Higgs boson, explore dark matter production in particle collisions, and potentially discover and study new phenomena. The project will develop data analysis techniques that could be used in big data contexts beyond f ....The top quark: a portal to new physics in particle colliders. This project aims to address fundamental questions of particle physics by studying the top quark, the most elementary particle known. The project will generate new knowledge about the top quark and the recently discovered Higgs boson, explore dark matter production in particle collisions, and potentially discover and study new phenomena. The project will develop data analysis techniques that could be used in big data contexts beyond fundamental research. The expected outcome of the project is to expand in a substantial way our understanding of the smallest components of matter and potentially, also of the largest structures of the Universe.Read moreRead less
Excitation spectra of quantum chromodynamics. Just as quantum electrodynamics describes the quantum mechanical excitation spectra of atomic systems, quantum chromodynamics (QCD) describes the excitation spectra of quark and gluon systems, such as the proton. This project will resolve the interactions underpinning the excitations of QCD, as being investigated at international facilities.
Interplay of the forces of nature: electroweak and strong interactions. The Large Hadron Collider in Switzerland will search for new physics by smashing protons together at the highest energies ever created in the laboratory. This project will focus on complementary searches for new physics by investigating novel phenomena associated with the mutual interactions of the strong and weak forces of nature.
Elucidating the role of quantum electrodynamics in hadron properties. This project will explore the fundamental mechanisms of nature making the neutron heavier than the proton; governing which nuclei are stable; and determining the current state of the Universe. Drawing on substantial supercomputing resources made available through international collaboration, this project will perform the first ab-initio simulation combining the quantum field theories governing elementary quarks, gluons, electr ....Elucidating the role of quantum electrodynamics in hadron properties. This project will explore the fundamental mechanisms of nature making the neutron heavier than the proton; governing which nuclei are stable; and determining the current state of the Universe. Drawing on substantial supercomputing resources made available through international collaboration, this project will perform the first ab-initio simulation combining the quantum field theories governing elementary quarks, gluons, electrons and photons; namely quantum chromodynamics and quantum electrodynamics. This project will develop novel theoretical and numerical techniques to confront the otherwise elusive electromagnetic contributions to hadronic properties and in doing so, address a wide range of important aspects of hadron structure and interactions.Read moreRead less
Structure of Hadronic Excitations from Lattice Quantum Chromodynamics. Quantum chromodynamics describes the fundamental strong interactions between quarks and gluons as they compose hadrons such as the proton or neutron. Beyond these lowest-energy systems, the quantum mechanical excitation spectra display a rich and complex structure. Remarkably, little is known about the internal structure of these states. The central goal of this project is to unveil the nature of hadrons and their excited sta ....Structure of Hadronic Excitations from Lattice Quantum Chromodynamics. Quantum chromodynamics describes the fundamental strong interactions between quarks and gluons as they compose hadrons such as the proton or neutron. Beyond these lowest-energy systems, the quantum mechanical excitation spectra display a rich and complex structure. Remarkably, little is known about the internal structure of these states. The central goal of this project is to unveil the nature of hadrons and their excited states using the first principles approach of lattice gauge theory. By elucidating aspects of hadron structure in terms of the most fundamental non-perturbative quark and gluon fields, the project will create new knowledge impacting on renowned experimental programs at international facilities.Read moreRead less
Electromagnetic structure of hadronic excitations from lattice quantum chromodynamics. Just as quantum electrodynamics describes the quantum mechanical excitation spectra of atomic systems, quantum chromodynamics (QCD) describes the excitation spectra of quark and gluon systems, such as the proton. This project will resolve the internal structure of the low-lying excitations of QCD, as being investigated at international facilities.