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
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
High Precision Silicon Pixel Detectors for High Energy Physics , Synchrotron and Medical Imaging Applications. Australia participates actively in the frontier field of high-energy particle physics to understand the fundamental building blocks of matter, their origins and interactions. This field excites the best minds in the scientific world and provides excellent training. To maintain our position in this field we must continue the development of the powerful instrumentation required for high- ....High Precision Silicon Pixel Detectors for High Energy Physics , Synchrotron and Medical Imaging Applications. Australia participates actively in the frontier field of high-energy particle physics to understand the fundamental building blocks of matter, their origins and interactions. This field excites the best minds in the scientific world and provides excellent training. To maintain our position in this field we must continue the development of the powerful instrumentation required for high-energy experiments. This project will satisfy that role. The application of particle detector expertise to state-of-the-art X-ray imaging detectors for the Australian Synchrotron and medical imaging is a perfect example of fundamental science tools applied to other fields. Australian Synchrotron experiments stand to gain much.Read moreRead less
Frontier Experiments in High Energy Physics. High energy particle physics studies the most fundamental constituents of matter. This microscopic frontier requires the highest energy and highest intensity particle accelerators. Through the Big Bang Model, high energy physics also sheds light on the development of the very early Universe. It is thus crucial for the understanding of nature at the very largest of scales as well as the very smallest. The ATLAS and Belle experiments probe two of the mo ....Frontier Experiments in High Energy Physics. High energy particle physics studies the most fundamental constituents of matter. This microscopic frontier requires the highest energy and highest intensity particle accelerators. Through the Big Bang Model, high energy physics also sheds light on the development of the very early Universe. It is thus crucial for the understanding of nature at the very largest of scales as well as the very smallest. The ATLAS and Belle experiments probe two of the most significant questions in fundamental physics: what is the origin of mass, and why do we live in a universe composed of matter rather than antimatter?
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Frontier Experiments in High Energy Physics. This project will support physicists in the expected era of discovery in the knowledge of fundamental particles that makes up our Universe. Having participated in developing the giant $½ billion ATLAS experiment, Australian scientists will be making major discoveries in this era. ATLAS will hunt down the Higgs boson, to understand the origin of mass of fundamental particles. It will also search for particles to explain Dark Matter, which makes up 25% ....Frontier Experiments in High Energy Physics. This project will support physicists in the expected era of discovery in the knowledge of fundamental particles that makes up our Universe. Having participated in developing the giant $½ billion ATLAS experiment, Australian scientists will be making major discoveries in this era. ATLAS will hunt down the Higgs boson, to understand the origin of mass of fundamental particles. It will also search for particles to explain Dark Matter, which makes up 25% of our Universe. ATLAS will search for undiscovered laws of nature to help us unify our understanding of the forces of nature. Excellent training and enhhancement of public interest, international cooperation and networking, and national pride will be provided by this project.Read moreRead less
New generation pulsed magnetron sputtering for the synthesis of advanced materials. Magnetron sputtering underpins the manufacture of many products ranging from semiconductor microelectronics to energy efficient windows. This project will create a new generation sputtering process fully compatible with current technology but capable of synthesising new phases and new film microstructures with greatly enhanced performance.