Cosmological vacuum stability as a window on fundamental physics. Vacuum is not just the absence of matter: it is the lowest-energy state of our Universe. This project aims to investigate the existence of new particles via their impacts upon the vacuum of the Universe. It expects to develop methods required to extract information on the existence of new particles from the vacuum, using transitions between different vacua, resulting gravitational waves, and results from a broad range of other co ....Cosmological vacuum stability as a window on fundamental physics. Vacuum is not just the absence of matter: it is the lowest-energy state of our Universe. This project aims to investigate the existence of new particles via their impacts upon the vacuum of the Universe. It expects to develop methods required to extract information on the existence of new particles from the vacuum, using transitions between different vacua, resulting gravitational waves, and results from a broad range of other complementary experiments. Expected outcomes include comprehensive tests of four of the most compelling theoretical frameworks for new particles. Significant expected benefits include advanced training for Australian students in numerical methods, software development, statistical analysis and research computing.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101427
Funder
Australian Research Council
Funding Amount
$462,265.00
Summary
Challenging the Standard Model with the LHCb experiment. This project aims to reveal the existence of elementary particles never observed before or of new forces of nature by studying data collected by the LHCb experiment. LHCb is situated at the world’s most powerful particle accelerator, the Large Hadron Collider. The studies are expected to generate new knowledge in the field of particle physics and could resolve long-standing puzzles such as the composition of the Universe. The project aims ....Challenging the Standard Model with the LHCb experiment. This project aims to reveal the existence of elementary particles never observed before or of new forces of nature by studying data collected by the LHCb experiment. LHCb is situated at the world’s most powerful particle accelerator, the Large Hadron Collider. The studies are expected to generate new knowledge in the field of particle physics and could resolve long-standing puzzles such as the composition of the Universe. The project aims at optimally exploiting LHCb data by using an innovative measurement approach based on advanced computational and machine learning techniques. It should enhance the capacity in particle physics and should create new collaborations with Europe, benefiting the diversity of the Australian physics programme.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100446
Funder
Australian Research Council
Funding Amount
$445,688.00
Summary
Exploring the Nature of Dark Matter. This project aims to address one of the key fundamental questions in physics: what is dark matter? Dark matter makes up 84% of the matter in the universe, but we do not know its identity. This project expects to improve our understanding of the fundamental properties of dark matter and how it interacts with ordinary matter. Expected outcomes include new theoretical models of dark matter that will guide future experiments, and precision calculations of intera ....Exploring the Nature of Dark Matter. This project aims to address one of the key fundamental questions in physics: what is dark matter? Dark matter makes up 84% of the matter in the universe, but we do not know its identity. This project expects to improve our understanding of the fundamental properties of dark matter and how it interacts with ordinary matter. Expected outcomes include new theoretical models of dark matter that will guide future experiments, and precision calculations of interactions between dark and ordinary matter that are needed to interpret experimental results. Benefits include enhancing Australian research capacity in an internationally active area of research and advanced student training. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100098
Funder
Australian Research Council
Funding Amount
$1,974,000.00
Summary
Enabling the Future of the Australian Collider Physics Program. The project aims to fund the continuation of Australia’s very successful experimental particle physics program to explore how the universe works at it's fundamental level. We interrogate subatomic matter at the energy frontier at CERN's Large Hadron Collider and the intensity frontier at Japan's SuperKEKB collider. The basic contributions required for Australian membership of these two key programs will enable scientists to continue ....Enabling the Future of the Australian Collider Physics Program. The project aims to fund the continuation of Australia’s very successful experimental particle physics program to explore how the universe works at it's fundamental level. We interrogate subatomic matter at the energy frontier at CERN's Large Hadron Collider and the intensity frontier at Japan's SuperKEKB collider. The basic contributions required for Australian membership of these two key programs will enable scientists to continue capitalising on decades of hard work and accumulated expertise, significant project outcomes and benefits include: access for Australia to advanced instruments and international research facilities; training of the next generation of researchers in detector construction and operation; and a rich science program.Read moreRead less
Tackling the computational bottleneck in precision particle physics. This project aims to deliver a breakthrough technique in theoretical-computational particle physics, with significant potential for high-precision applications. The project targets some of the most advanced and resource-intensive calculations in particle physics, which are widely used but currently limited by extremely high computational resource requirements. This project expects to develop a novel approach that will vastly re ....Tackling the computational bottleneck in precision particle physics. This project aims to deliver a breakthrough technique in theoretical-computational particle physics, with significant potential for high-precision applications. The project targets some of the most advanced and resource-intensive calculations in particle physics, which are widely used but currently limited by extremely high computational resource requirements. This project expects to develop a novel approach that will vastly reduce the computational complexity while at the same time improving their accuracy relative to the current global state of the art. Expected outcomes include the new methodology itself as well as a full-fledged and open-access simulation code based on it, which should be highly efficient.Read moreRead less
Probing for physics beyond the Standard Model in Lepton Flavour Violation. The Standard Model of Particle Physics describes the fundamental particles of which matter in the Universe is composed, and the interactions which bind these particles. It is one of the most precisely measured and validated theories which science has produced, and there has as yet been no measurement of fundamental particle interactions which is in conflict with its predictions. This project involving a large internation ....Probing for physics beyond the Standard Model in Lepton Flavour Violation. The Standard Model of Particle Physics describes the fundamental particles of which matter in the Universe is composed, and the interactions which bind these particles. It is one of the most precisely measured and validated theories which science has produced, and there has as yet been no measurement of fundamental particle interactions which is in conflict with its predictions. This project involving a large international team and highly sophisticated technology will search for evidence of physics beyond the Standard Model by looking for conversion of muons to electrons a reaction which the model prohibits. Observation of this process would be evidence of new particles and interactions, and would revolutionise our understanding of nature.Read moreRead less
Electroweak phase transition: A cosmological window to new particle physics. The observed asymmetry between matter and antimatter in the visible universe arguably represents the major challenge to contemporary particle physics and cosmology. This project explores new theoretical, phenomenological and computational aspects of the electroweak phase transition and the generation of the cosmic matter-antimatter asymmetry in the early universe together with their links to new physics that may manifes ....Electroweak phase transition: A cosmological window to new particle physics. The observed asymmetry between matter and antimatter in the visible universe arguably represents the major challenge to contemporary particle physics and cosmology. This project explores new theoretical, phenomenological and computational aspects of the electroweak phase transition and the generation of the cosmic matter-antimatter asymmetry in the early universe together with their links to new physics that may manifest at present and future high-energy colliders and gravitational wave observatories. Read moreRead less
Understanding physics through flexible calculations. This project aims to explore and interpret physics at the high energy frontier with calculations and computational techniques. It will develop and apply techniques and software to arbitrary physics models and make predictions in models. This will expand the set of ideas that can be rigorously scrutinised using data from collider and astrophysical experiments. This may shed light on the origin of dark matter and why the Higgs mass is so light, ....Understanding physics through flexible calculations. This project aims to explore and interpret physics at the high energy frontier with calculations and computational techniques. It will develop and apply techniques and software to arbitrary physics models and make predictions in models. This will expand the set of ideas that can be rigorously scrutinised using data from collider and astrophysical experiments. This may shed light on the origin of dark matter and why the Higgs mass is so light, and expand understanding of nature at the most foundational level.Read moreRead less
Measuring critical background in the Australian search for dark matter. This project aims to develop ultra-sensitive detector technology essential for SABRE, a world-wide experiment with detectors in both the Northern and Southern Hemispheres which are operated together to directly detect the dark matter halo of our Milky Way galaxy. Dark matter makes up nearly five times more mass in the universe than everything we can see, yet it has never been detected in the laboratory. SABRE South will be i ....Measuring critical background in the Australian search for dark matter. This project aims to develop ultra-sensitive detector technology essential for SABRE, a world-wide experiment with detectors in both the Northern and Southern Hemispheres which are operated together to directly detect the dark matter halo of our Milky Way galaxy. Dark matter makes up nearly five times more mass in the universe than everything we can see, yet it has never been detected in the laboratory. SABRE South will be installed in the Stawell Underground Physics Laboratory in a goldmine in Victoria, Australia. Dark matter is not the only thing SABRE can detect. The project will measure all possible types of naturally occurring radiation, from space, the surrounding rock, and the detectors themselves, that can blind SABRE to dark matter.Read moreRead less