Converging on new particles and fundamental symmetries. The goal of this project is to test theories for new particles and fundamental symmetries. By using advanced computational and statistical methods to combine all relevant data from many different experiments with a large number of different theoretical predictions, it expects to reveal just how well different theories actually describe reality. This will help us to understand what new particles and fundamental symmetries exist beyond thos ....Converging on new particles and fundamental symmetries. The goal of this project is to test theories for new particles and fundamental symmetries. By using advanced computational and statistical methods to combine all relevant data from many different experiments with a large number of different theoretical predictions, it expects to reveal just how well different theories actually describe reality. This will help us to understand what new particles and fundamental symmetries exist beyond those we already know. It will lead to new algorithms and computational methods in machine learning and statistical sampling, and will train a cohort of graduates highly skilled in statistical data science and research computing.Read moreRead less
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.
Relating string theory and particle physics. Currently, string theory is the only consistent candidate to provide unification of gravity with the other fundamental interactions. This project will discover a deeper interplay between string theory and elementary particle physics that would bring string theory closer to the real world.
Virtual colliders: high-accuracy models for high energy physics. This project will create an advanced and general model of high-energy processes, focusing on the Large Hadron Collider at CERN. New analytical and numerical solutions will be developed and combined to reach unprecedented accuracy and detail. This will clarify important phenomenological questions in the Standard Model and will enable more precise searches for deviations from it (new physics). A publicly available numerical code will ....Virtual colliders: high-accuracy models for high energy physics. This project will create an advanced and general model of high-energy processes, focusing on the Large Hadron Collider at CERN. New analytical and numerical solutions will be developed and combined to reach unprecedented accuracy and detail. This will clarify important phenomenological questions in the Standard Model and will enable more precise searches for deviations from it (new physics). A publicly available numerical code will be produced, with a large number of applications. These include, for instance, precision extraction of fundamental parameters and improved absolute calibrations of experimental measurements, explicit theoretical modelling of new physics phenomena, and optimisation of detector design and analysis strategies.Read moreRead less
Quest for dark matter and new phenomena at the energy frontier. This project aims to develop technologies and techniques to detect dark matter. Particle physics research seeks to understand the universe at its most fundamental level. The Higgs boson discovery confirmed the Standard Model of particle physics, but many fundamental questions about the microscopic nature of the universe remain. The universe predominantly consists of dark matter, which the particles within the Standard Model do not e ....Quest for dark matter and new phenomena at the energy frontier. This project aims to develop technologies and techniques to detect dark matter. Particle physics research seeks to understand the universe at its most fundamental level. The Higgs boson discovery confirmed the Standard Model of particle physics, but many fundamental questions about the microscopic nature of the universe remain. The universe predominantly consists of dark matter, which the particles within the Standard Model do not explain. The Large Hadron Collider and Australia’s SABRE provide a huge opportunity to discover physics processes by enabling searches for new particles at the high-energy frontier and the direct detection of dark matter.Read moreRead less
Probing the structure of exotic mesons, at the Large Hadron Collider and beyond. Unexpected new particles, outside the bounds of current textbooks, present one of the most interesting puzzles in physics. This project will search for more of these particles at the Large Hadron Collider at CERN, and at new facilities in Japan and Germany that will change particle physics in the coming decade.
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
Beyond Higgs: Exploring the high-energy frontier. The recent discovery of the Higgs boson confirmed the remaining element of the Standard Model of particle physics, yet many fundamental questions about the microscopic nature of the Universe remain. Observations have shown the Universe to predominantly consist of dark matter, which is not explained by the particles within the Standard Model. The Large Hadron Collider upgrades provide a huge opportunity to discover new physics processes by enablin ....Beyond Higgs: Exploring the high-energy frontier. The recent discovery of the Higgs boson confirmed the remaining element of the Standard Model of particle physics, yet many fundamental questions about the microscopic nature of the Universe remain. Observations have shown the Universe to predominantly consist of dark matter, which is not explained by the particles within the Standard Model. The Large Hadron Collider upgrades provide a huge opportunity to discover new physics processes by enabling direct searches for new particles at the high-energy frontier. This project aims to fully exploit the unique datasets anticipated, and develop key electronic components and new techniques. It will expand the reach of the ATLAS experiment at the Large Hadron Collider and cement Australia’s role at the forefront of particle physics.Read moreRead less
Fundamental physics with the large scale structure of the Universe. Using data from upcoming galaxy and weak gravitational lensing surveys, this project aims to address fundamental questions of cosmology: how massive are neutrinos? Are there exotic relativistic matter components? How exactly were the initial density fluctuations generated? Current theoretical predictions of the growth of cosmic structures are not able to match the expected precision of future measurements. This project aims to s ....Fundamental physics with the large scale structure of the Universe. Using data from upcoming galaxy and weak gravitational lensing surveys, this project aims to address fundamental questions of cosmology: how massive are neutrinos? Are there exotic relativistic matter components? How exactly were the initial density fluctuations generated? Current theoretical predictions of the growth of cosmic structures are not able to match the expected precision of future measurements. This project aims to solve this problem and allow for the full harnessing of discovery potential of the observations. By combining numerical simulations of the Universe with a machine-learning algorithm, accurate and efficient estimation of cosmological parameters will be made possible.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