New Techniques for New Physics Searches at the CERN Large Hadron Collider. This project aims to break new ground in the quest to discover the existence of new fundamental constituents of nature. In order to achieve this, the team will invent and deploy a suite of advanced machine learning and anomaly detection techniques, developed by the chief investigators, to mine the data processed and collected with the ATLAS experiment at the CERN Large Hadron Collider throughout the entirety of the next d ....New Techniques for New Physics Searches at the CERN Large Hadron Collider. This project aims to break new ground in the quest to discover the existence of new fundamental constituents of nature. In order to achieve this, the team will invent and deploy a suite of advanced machine learning and anomaly detection techniques, developed by the chief investigators, to mine the data processed and collected with the ATLAS experiment at the CERN Large Hadron Collider throughout the entirety of the next data taking run. Expected outcomes of this project include the first application of revolutionary anomaly detection methods to fundamental physics, probing unexplored space in the process, and enhancing the capacity and development of future leaders in Australian science and technology at the forefront of data analytics.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
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
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
Emergent phenomena in quantum chromodynamics. This project aims to understand the transition from quarks and gluons (partons) to hadrons in quantum chromodynamics (QCD). It will develop and combine a treatment of quantum corrections to high-energy processes with a revised picture of how colour strings break up into hadrons. This Project will shed new light on fundamental questions of the strong nuclear force. It will improve the precision and efficiency of the leading open-source particle-physic ....Emergent phenomena in quantum chromodynamics. This project aims to understand the transition from quarks and gluons (partons) to hadrons in quantum chromodynamics (QCD). It will develop and combine a treatment of quantum corrections to high-energy processes with a revised picture of how colour strings break up into hadrons. This Project will shed new light on fundamental questions of the strong nuclear force. It will improve the precision and efficiency of the leading open-source particle-physics code, and bring them to bear on particle collisions at the Large Hadron Collider, increasing its potential for accurate measurements and new discoveries. It will lead to a better understanding of the complex emergent dynamics in QCD and an open-source code with broad applications, including significantly more reliable calculations of numerous high-energy processes.Read moreRead less
New Physics and the quark/lepton family replication puzzle. This project aims to investigate how new physics impacts on the puzzling threefold replication of the elementary particles known as quarks and leptons; these particles provide the foundations for the structure of atoms. This theory project seeks to do so in the context of a concentrated worldwide experimental program whose objective is to produce hugely more information about the mysterious replication. Expected outcomes include the con ....New Physics and the quark/lepton family replication puzzle. This project aims to investigate how new physics impacts on the puzzling threefold replication of the elementary particles known as quarks and leptons; these particles provide the foundations for the structure of atoms. This theory project seeks to do so in the context of a concentrated worldwide experimental program whose objective is to produce hugely more information about the mysterious replication. Expected outcomes include the construction of new theories that deepen our understanding of elementary particles and their interactions. This should provide significant benefits to intellectual culture and the training of early-career researchers as flexible problem solvers able to innovate in any context in industry or government service.Read moreRead less
Search for physics beyond the Standard Model in penguin decays. In the decays of subatomic particles, there is an increasing number of discrepancies between the theoretical expectations and the measurements. This project aims to confirm or refute the interpretation of these results as arising from phenomena not described by the Standard Model of Particle Physics. The project expects to generate new knowledge to clarify this question by making an innovative set of measurements that are designed t ....Search for physics beyond the Standard Model in penguin decays. In the decays of subatomic particles, there is an increasing number of discrepancies between the theoretical expectations and the measurements. This project aims to confirm or refute the interpretation of these results as arising from phenomena not described by the Standard Model of Particle Physics. The project expects to generate new knowledge to clarify this question by making an innovative set of measurements that are designed to minimise existing theoretical uncertainty. The expected outcomes are a deeper understanding of how the Universe works and an enhanced capability to collaborate internationally in Particle Physics. Significant benefits will be provided in terms of training in advanced computational methods.Read moreRead less
Rare decays of B mesons: Probing new physics with Belle II. This project aims to observe the decay of a B meson to a muon and a neutrino, a rare subatomic process. This will test understanding of the basic building blocks and forces of nature. If the measured and expected decay rates are different, this would be significant. The project also seeks to enhance Australia's role in a major physics experiment based in Japan. This project will contribute to a deeper understanding of our place in the U ....Rare decays of B mesons: Probing new physics with Belle II. This project aims to observe the decay of a B meson to a muon and a neutrino, a rare subatomic process. This will test understanding of the basic building blocks and forces of nature. If the measured and expected decay rates are different, this would be significant. The project also seeks to enhance Australia's role in a major physics experiment based in Japan. This project will contribute to a deeper understanding of our place in the Universe.Read moreRead less
Optimising the search for the next discovery in particle physics. This project aims to uncover the new theory of particle physics that can simultaneously explain the Higgs mechanism, the presence of dark matter and the current abundance of matter over antimatter in our universe. This is not possible with current theories. This project aims to find viable theories using a wide range of data from particle astrophysics and collider experiments. With the resulting knowledge, this project aims to des ....Optimising the search for the next discovery in particle physics. This project aims to uncover the new theory of particle physics that can simultaneously explain the Higgs mechanism, the presence of dark matter and the current abundance of matter over antimatter in our universe. This is not possible with current theories. This project aims to find viable theories using a wide range of data from particle astrophysics and collider experiments. With the resulting knowledge, this project aims to design, optimise and implement better searches for new physics at the Large Hadron Collider (LHC). The new LHC results will be used to either determine the correct explanation for any new discoveries or alternatively to provide definitive limits on new theories. The results will be used to make high impact statements on the design of future facilities.Read moreRead less
Neutrino masses at the precision frontier. Australia actively participates in particle physics, which studies the fundamental constituents of matter and their interactions a fraction of a second after the universe began. This project will play a crucial role in understanding one of the fundamental building blocks of the Universe. It will promote international cooperation and national pride.