Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100006
Funder
Australian Research Council
Funding Amount
$600,000.00
Summary
An adaptable and dedicated linear accelerator for medical radiation research. Leading radiation scientists developing innovative methods and devices for treating cancer patients will collaborate in future research using this highly adaptable linear accelerator for medical radiation research. Innovations in tumour targeting, better patient safety, new medical devices and improved cancer outcomes are expected.
A phenomenological approach to improve radioembolisation treatment of cancer. In recent years, radioembolisation for liver cancer has become an effective therapeutic option. However, it is likely that patients are being “under-treated” as doses remain based on results from external radiation therapy. This project will develop a phenomenological approach to radionuclide therapy to improve outcomes for cancer patients.
The Surface Science of Vacuum Glazing. In order to achieve a stable vacuum in evacuated glazing, high temperature baking during evacuation is required. The high temperature processing prevents the use of strengthened glass, such as tempered glass. However, samples made at low temperatures suffer from poor vacuum characteristics, particularly when exposed to UV radiation. In this project, we aim to discover the chemical and physical processes occurring on the glass surface responsible for vacuum ....The Surface Science of Vacuum Glazing. In order to achieve a stable vacuum in evacuated glazing, high temperature baking during evacuation is required. The high temperature processing prevents the use of strengthened glass, such as tempered glass. However, samples made at low temperatures suffer from poor vacuum characteristics, particularly when exposed to UV radiation. In this project, we aim to discover the chemical and physical processes occurring on the glass surface responsible for vacuum degradation. We will use this knowledge to develop a low temperature manufacturing process that can be used with tempered glass and results in a high-quality vacuum, stable over the device service life.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100433
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Optimising light harvesting using quantum transport. Observations of wavelike energy transport in photosynthetic systems have exposed the role of quantum mechanics in natural light harvesting. This project is a study of how light harvesting functions for an incoherent source like sunlight. In sunlight, energy transport occurs at steady state, a dramatically simpler regime than when a coherent source like lasers are used. This project will exploit this simplification to develop new methods for tr ....Optimising light harvesting using quantum transport. Observations of wavelike energy transport in photosynthetic systems have exposed the role of quantum mechanics in natural light harvesting. This project is a study of how light harvesting functions for an incoherent source like sunlight. In sunlight, energy transport occurs at steady state, a dramatically simpler regime than when a coherent source like lasers are used. This project will exploit this simplification to develop new methods for treating light harvesting in sunlight and apply them to a variety of natural and artificial systems. It will clarify how bacteria and plants harvest sunlight and lead to design principles that will enable artificial light harvesting to take advantage of quantum effects.Read moreRead less
Many-body problems. The discovery of new superheavy elements, chemical evolution of the Universe, nuclear reactions deep under the Coulomb barrier in nuclear reactors, in stars and during the Big Bang Nucleosynthesis, accuracy of precise atomic clocks, consistency of the Standard Model in strong fields are among the most vital problems of modern science. This project suggests several new ideas in these areas, which are based on knowledge accumulated in different research fields. The outcomes of ....Many-body problems. The discovery of new superheavy elements, chemical evolution of the Universe, nuclear reactions deep under the Coulomb barrier in nuclear reactors, in stars and during the Big Bang Nucleosynthesis, accuracy of precise atomic clocks, consistency of the Standard Model in strong fields are among the most vital problems of modern science. This project suggests several new ideas in these areas, which are based on knowledge accumulated in different research fields. The outcomes of the research will help Australia to build up a "critical mass" of scientific expertise, which is necessary to place and keep it among leaders in these frontier areas of physics, and to train the next generation of experts in these fields.Read moreRead less
Modelling quantum dynamics of electronic excited states in complex molecular materials. Understanding new materials that are the basis of new sources of renewable energy sources represents a major scientific challenge. Many of these materials are composed of large organic molecules containing hundreds of atoms. Their properties and the concepts needed to understand these materials are distinctly different from semiconductors such as silicon. This research will enhance our ability to design bett ....Modelling quantum dynamics of electronic excited states in complex molecular materials. Understanding new materials that are the basis of new sources of renewable energy sources represents a major scientific challenge. Many of these materials are composed of large organic molecules containing hundreds of atoms. Their properties and the concepts needed to understand these materials are distinctly different from semiconductors such as silicon. This research will enhance our ability to design better materials and optimize the performance of organic solar cells and LEDs. Australia's capacity for research and development in this scientifically challenging and technologically important field will be enhanced by this project. Read moreRead less
Atomic tests of unification theories. Although the standard model of particle physics has withstood decades of intensive experimental tests, it is widely believed to be merely a low-energy manifestation of a "true" theory that unifies the four forces of nature. While some searches for new physics beyond the standard model are performed at high-energy particle accelerators, a very sensitive probe can be done at low energies in atomic and molecular measurements of weak interaction effects. This pr ....Atomic tests of unification theories. Although the standard model of particle physics has withstood decades of intensive experimental tests, it is widely believed to be merely a low-energy manifestation of a "true" theory that unifies the four forces of nature. While some searches for new physics beyond the standard model are performed at high-energy particle accelerators, a very sensitive probe can be done at low energies in atomic and molecular measurements of weak interaction effects. This project is devoted to a theoretical investigation of weak interaction effects in atoms, molecules, and nuclei. It will provide improved tests of unified theories.Read moreRead less
Violation of fundamental symmetries in atoms, molecules and nuclei. This theoretical project aims to predict enhanced effects of parity (P), time reversal (T), CP and Lorentz invariance violation, which may be measured using atomic spectroscopy and nuclear physics methods. This project expects to contribute to search for physics beyond standard model, including standard model extensions predicting axion, dark matter and T,P-violating electric dipole moments. Expected outcomes include predictions ....Violation of fundamental symmetries in atoms, molecules and nuclei. This theoretical project aims to predict enhanced effects of parity (P), time reversal (T), CP and Lorentz invariance violation, which may be measured using atomic spectroscopy and nuclear physics methods. This project expects to contribute to search for physics beyond standard model, including standard model extensions predicting axion, dark matter and T,P-violating electric dipole moments. Expected outcomes include predictions of new enhanced effects in nuclei, atoms and molecules. By-products and benefits include development of high precision computer codes for atomic calculations, which are expected to have numerous applications including photon and electron processes, properties of superheavy elements and atomic clocks.Read moreRead less
Atomic clocks, space-time variation of fundamental constants, violation of fundamental symmetries and tests of unification theories. The project will help to establish Australia among the leaders in important areas of modern science: tests of theories unifying all physical forces and cosmology, search for variation of the fundamental forces of Nature and making super precise atomic clocks. The atomic clocks are used in all navigation (current GPS and future Galileo) systems and many other import ....Atomic clocks, space-time variation of fundamental constants, violation of fundamental symmetries and tests of unification theories. The project will help to establish Australia among the leaders in important areas of modern science: tests of theories unifying all physical forces and cosmology, search for variation of the fundamental forces of Nature and making super precise atomic clocks. The atomic clocks are used in all navigation (current GPS and future Galileo) systems and many other important applications. The training of students and researchers combined with a rich international collaborative program will insure that Australia is well placed to prepare for the approaching revolution in physics and cosmology.Read moreRead less
Violation of fundamental symmetries and test of unification models. This project is devoted to a theoretical investigation of the atomic and nuclear effects of parity and time invariance violation. Measurements of these effects provide accurate tests of unification theories of elementary particles. Effects of weak interactions are normally very small, and we want to look for possibilities to enhance these effects. We also plan to search for new effects and tests of the unification theories an ....Violation of fundamental symmetries and test of unification models. This project is devoted to a theoretical investigation of the atomic and nuclear effects of parity and time invariance violation. Measurements of these effects provide accurate tests of unification theories of elementary particles. Effects of weak interactions are normally very small, and we want to look for possibilities to enhance these effects. We also plan to search for new effects and tests of the unification theories and develop accurate method of atomic calculations.Read moreRead less