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Heavy atoms and ions and precision tests of fundamental physics. This project aims to further the understanding of the structure of heavy atoms through development and application of state-of-the-art many-electron methods. Atomic physics is undergoing a period of rapid growth with a new generation of experiments underway across different areas in fundamental physics. This includes testing particle physics at low energies, opening a new realm of discovery with the synthesis and interrogation of s ....Heavy atoms and ions and precision tests of fundamental physics. This project aims to further the understanding of the structure of heavy atoms through development and application of state-of-the-art many-electron methods. Atomic physics is undergoing a period of rapid growth with a new generation of experiments underway across different areas in fundamental physics. This includes testing particle physics at low energies, opening a new realm of discovery with the synthesis and interrogation of superheavy elements, and the development of atomic clocks of ever-increasing precision. The expected benefit will be to increase capability in fundamental physics tests and in the development of precision atomic instruments.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
Discovering new physics with the Large Hadron Collider. This project aims to apply and develop new methods of machine learning to particle physics beyond the Standard Model. The project will develop high-end analytical and computational techniques necessary to analyse particle physics results from the Large Hadron Collider. These techniques should enable exciting new measurements to be carried out, enhance the likelihood of discovering new phenomena in current and future particle colliders, and ....Discovering new physics with the Large Hadron Collider. This project aims to apply and develop new methods of machine learning to particle physics beyond the Standard Model. The project will develop high-end analytical and computational techniques necessary to analyse particle physics results from the Large Hadron Collider. These techniques should enable exciting new measurements to be carried out, enhance the likelihood of discovering new phenomena in current and future particle colliders, and rule out incorrect theories.Read moreRead less
Explaining the dark matter small-scale crisis with spectral distortions. This project aims to explain the nature of dark matter and provide a solution to the so-called small-scale crisis. The "cold dark matter" model provides an excellent fit to observations of the universe on the largest scales. Yet, it appears to be in conflict with current understanding of how small structures such as dwarf galaxies form. This project expects to determine the distortions to the blackbody spectrum of the cosmi ....Explaining the dark matter small-scale crisis with spectral distortions. This project aims to explain the nature of dark matter and provide a solution to the so-called small-scale crisis. The "cold dark matter" model provides an excellent fit to observations of the universe on the largest scales. Yet, it appears to be in conflict with current understanding of how small structures such as dwarf galaxies form. This project expects to determine the distortions to the blackbody spectrum of the cosmic microwave background (CMB) photons due to different solutions to this small-scale crisis. The expected outcome is to open an observational pathway to test these solutions with the future CMB observations. This project will provide significant contribution to both particle physics and astrophysics/astronomy, and will advance Australia’s knowledge base in fundamental science beyond the immediate goal of clarifying small-scale problems of cold dark matter.Read moreRead less
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
New physics with strongly correlated and spin-orbit-coupled electrons. This project aims to identify new physics in quantum magnets and emergent phenomena in solids where the electrons are strongly coupled and intertwined in a complex manner. As a consequence, quantum effects are dramatically enhanced and, in certain situations, force the electrons to split into different exotic particles. This project expects to identify suitable physical systems, candidate materials and appropriate conditions ....New physics with strongly correlated and spin-orbit-coupled electrons. This project aims to identify new physics in quantum magnets and emergent phenomena in solids where the electrons are strongly coupled and intertwined in a complex manner. As a consequence, quantum effects are dramatically enhanced and, in certain situations, force the electrons to split into different exotic particles. This project expects to identify suitable physical systems, candidate materials and appropriate conditions required for the experimental observation of this phenomena with neutron scattering methods. The advanced materials and exotic particles identified in this project will inform the development of next generation technologies, becoming the quantum bits in future quantum computers.Read moreRead less
Dissecting cell cycle regulation using programmable gene editing technology. This program aims to harness the unprecedented power of CRISPR-Cas13 gene-editing technology to develop high-throughput tools to explore the role of RNA regulation in cell cycle control. This project expects to generate new knowledge about cell division and RNA biology by utilizing this new technology and applying interdisciplinary approaches. Expected outcomes of this proposal include new research tools capable of broa ....Dissecting cell cycle regulation using programmable gene editing technology. This program aims to harness the unprecedented power of CRISPR-Cas13 gene-editing technology to develop high-throughput tools to explore the role of RNA regulation in cell cycle control. This project expects to generate new knowledge about cell division and RNA biology by utilizing this new technology and applying interdisciplinary approaches. Expected outcomes of this proposal include new research tools capable of broadly addressing biological questions across multiple disciplines (e.g. from health to food production). This project intends to provide significant benefits, such as enhanced biological knowledge, multidisciplinary training opportunities and will build Australia’s capability in this rapidly expanding field.Read moreRead less
Iron-based high-temperature topological superconductors. Because of topological non-trivial nature and zero resistance, topological superconductors are very promising in the application of future electronic devices. This project aims to achieve intrinsic and robust topological superconductors at high-temperature by engineering iron-based superconductors via precisely controlling the defects, chemical doping, interface and substrates. Expected outcomes of this project will include high-temperatur ....Iron-based high-temperature topological superconductors. Because of topological non-trivial nature and zero resistance, topological superconductors are very promising in the application of future electronic devices. This project aims to achieve intrinsic and robust topological superconductors at high-temperature by engineering iron-based superconductors via precisely controlling the defects, chemical doping, interface and substrates. Expected outcomes of this project will include high-temperature iron-based topological superconductors as new material platforms for the study of exotic properties of topological superconductivity and future application in high-temperature fault-tolerant quantum computing. Read moreRead less
The nature and fate of quasiparticles in correlated quantum matter. The revolution in electronics and the Information Age were enabled by powerful theories based on the concept of the quasiparticle, an object composed of many particles such as electrons. This Fellowship aims to unravel the behaviour of new complex materials by investigating the nature of quasiparticles beyond the current paradigm. The key innovation is the use of trapped atoms, which allows new quantum theories and computational ....The nature and fate of quasiparticles in correlated quantum matter. The revolution in electronics and the Information Age were enabled by powerful theories based on the concept of the quasiparticle, an object composed of many particles such as electrons. This Fellowship aims to unravel the behaviour of new complex materials by investigating the nature of quasiparticles beyond the current paradigm. The key innovation is the use of trapped atoms, which allows new quantum theories and computational tools to be developed and precisely tested. The new knowledge generated by the Fellowship will advance a range of fields, including condensed matter physics, and could ultimately underpin a new generation of quantum devices featuring robust data memories, where information can be efficiently stored and extracted.Read moreRead less
Few-body correlations in many-particle quantum matter. This project aims to develop theories of quantum matter by investigating the connection between microscopic few-particle correlations and macroscopic quantum phenomena. The growing class of strongly correlated quantum systems that defy a conventional explanation creates a pressing need for this approach. This project will use the clean and tuneable cold-atom system, where microscopic properties are precisely known, to directly verify new spe ....Few-body correlations in many-particle quantum matter. This project aims to develop theories of quantum matter by investigating the connection between microscopic few-particle correlations and macroscopic quantum phenomena. The growing class of strongly correlated quantum systems that defy a conventional explanation creates a pressing need for this approach. This project will use the clean and tuneable cold-atom system, where microscopic properties are precisely known, to directly verify new spectral techniques. A greater understanding of quantum correlations is expected to advance several fields including condensed matter physics, and could underpin quantum devices where energy can be efficiently stored and rapidly extracted.Read moreRead less