Industrial Transformation Training Centres - Grant ID: IC230100036
Funder
Australian Research Council
Funding Amount
$4,999,600.00
Summary
ARC Training Centre for Radiation Innovation. This Centre aims to train the next generation of transdisciplinary leaders to enable, grow and transform industries that utilise or are impacted by radiation. Rapid growth in the natural resources, health, space and national security sectors urgently requires a highly capable workforce with scientific and regulatory knowledge to develop new technologies and social licence needs to maximise benefits. Outcomes include new methods of radiopharmaceutical ....ARC Training Centre for Radiation Innovation. This Centre aims to train the next generation of transdisciplinary leaders to enable, grow and transform industries that utilise or are impacted by radiation. Rapid growth in the natural resources, health, space and national security sectors urgently requires a highly capable workforce with scientific and regulatory knowledge to develop new technologies and social licence needs to maximise benefits. Outcomes include new methods of radiopharmaceutical production, more resilient spacecraft and robust regulatory frameworks. Industries and communities will benefit from a future workforce prepared for safe adoption, development and delivery of emerging techniques and advanced radiation technologies, enhancing Australia’s prosperity and security.Read moreRead less
ARC Centre of Excellence for Dark Matter Particle Physics. The Centre of Excellence for Dark Matter Particle Physics will deliver breakthroughs in our understanding of the Universe through the pursuit of the discovery of dark matter particles which comprise 80% of the mass of the universe. It assembles for the first time a strong and diverse team of physicists from particle, nuclear, and quantum physics as well as particle astrophysics. It will deliver high-profile experiments using new cutting- ....ARC Centre of Excellence for Dark Matter Particle Physics. The Centre of Excellence for Dark Matter Particle Physics will deliver breakthroughs in our understanding of the Universe through the pursuit of the discovery of dark matter particles which comprise 80% of the mass of the universe. It assembles for the first time a strong and diverse team of physicists from particle, nuclear, and quantum physics as well as particle astrophysics. It will deliver high-profile experiments using new cutting-edge technologies. The Centre will exploit the unique geographical location of the first underground physics lab in the Southern Hemisphere. The ultra-sensitive detectors and ultra-low radiation techniques will translate into a broad range of industrial applications and train a new generation of scientists.Read moreRead less
Ion-atom collision data for fusion energy, hadron therapy and astrophysics. This project aims to combine experimental and theoretical efforts to generate accurate data required for the development and maintenance of fusion reactors, treatment planning in hadron therapy of cancerous tumours, and modelling astrophysical phenomena. Hadron therapy has been used successfully worldwide for over a decade with Australia’s first such facility, the Bragg Centre for Proton Therapy, currently under construc ....Ion-atom collision data for fusion energy, hadron therapy and astrophysics. This project aims to combine experimental and theoretical efforts to generate accurate data required for the development and maintenance of fusion reactors, treatment planning in hadron therapy of cancerous tumours, and modelling astrophysical phenomena. Hadron therapy has been used successfully worldwide for over a decade with Australia’s first such facility, the Bragg Centre for Proton Therapy, currently under construction. Fusion reactors are a source of abundant green energy. Immense progress is being made in their construction and underlying technology. Currently, there is an urgent demand for accurate data on ion-beam collisions with atoms and molecules for the aforementioned applications. This project intends to meet this demand.Read moreRead less
Electron-molecule collisions in fusion and astrophysical plasmas. This project will apply innovative methods developed in Australia to accurately model electron collisions with diatomic hydrides. It will generate new knowledge of the dynamics underlying fundamental chemical reactions, and bring international scientists together to study the influence of molecules in plasmas more accurately than ever before. Outcomes will include essential diagnostics for fusion reactors, methods for using the Ja ....Electron-molecule collisions in fusion and astrophysical plasmas. This project will apply innovative methods developed in Australia to accurately model electron collisions with diatomic hydrides. It will generate new knowledge of the dynamics underlying fundamental chemical reactions, and bring international scientists together to study the influence of molecules in plasmas more accurately than ever before. Outcomes will include essential diagnostics for fusion reactors, methods for using the James Webb Space Telescope to study astrophysical clouds, and strengthened ties between Australia and the global plasma physics community. The significant benefits will include accelerating the development of fusion technology as an alternative to fossil fuels, and furthering our understanding of stellar evolution.Read moreRead less
Antihydrogen formation. This project aims to advance fundamental understanding of collisions involving antimatter. The dominance of matter over antimatter in the Universe is one of the most intriguing questions of today’s science. Researchers at the European Organisation for Nuclear Research (CERN) are addressing this question by creating antihydrogen and studying its properties, including the gravitational behaviour. By trapping and cooling antihydrogen positive ions, ultra-cold antihydrogen at ....Antihydrogen formation. This project aims to advance fundamental understanding of collisions involving antimatter. The dominance of matter over antimatter in the Universe is one of the most intriguing questions of today’s science. Researchers at the European Organisation for Nuclear Research (CERN) are addressing this question by creating antihydrogen and studying its properties, including the gravitational behaviour. By trapping and cooling antihydrogen positive ions, ultra-cold antihydrogen atoms can be created and used in free fall experiments at CERN. The convergent close-coupling method and threshold theory will be used to provide the necessary theoretical guidance for the experimental antihydrogen positive ion formation via low-energy positronium-antiproton and positronium-antihydrogen collisions.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100176
Funder
Australian Research Council
Funding Amount
$349,987.00
Summary
Quantum studies of dissociative electron attachment to molecules. The ability to predict the outcomes of molecular collisions is a difficult, yet important, problem with many applications in science and industry. Recent work at Curtin University has led to the first complete solution of the electronic part of the scattering problem for collisions with the hydrogen molecule, a major breakthrough in the field. This project will build on this progress to accurately model the nuclear motion during c ....Quantum studies of dissociative electron attachment to molecules. The ability to predict the outcomes of molecular collisions is a difficult, yet important, problem with many applications in science and industry. Recent work at Curtin University has led to the first complete solution of the electronic part of the scattering problem for collisions with the hydrogen molecule, a major breakthrough in the field. This project will build on this progress to accurately model the nuclear motion during collisions, which will enable the first calculations of molecular dissociation processes without the use of approximations. The data which will be produced is highly sought-after in fusion energy and astrophysics applications.Read moreRead less
A New Spin on Liquid Hydrogen: Controlled Cold Energy. While hydrogen is set to play a leading role in global decarbonisation, significant challenges remain regarding methods for its reliable storage and transportation. Hydrogen liquefaction has emerged as a promising approach in this regard due to its high energy density and hydrogen purity, but is currently prohibitively expensive. In this project we will exploit the peculiar spin physics of hydrogen to alleviate liquefactions costs through t ....A New Spin on Liquid Hydrogen: Controlled Cold Energy. While hydrogen is set to play a leading role in global decarbonisation, significant challenges remain regarding methods for its reliable storage and transportation. Hydrogen liquefaction has emerged as a promising approach in this regard due to its high energy density and hydrogen purity, but is currently prohibitively expensive. In this project we will exploit the peculiar spin physics of hydrogen to alleviate liquefactions costs through the provision of controllable refrigeration (so-called 'cold energy') following regasification. In particular we will measure, optimise and exploit the highly endothermic catalysed conversion of para- to ortho- hydrogen, which can provide up to 525 kJ/kg of cooling at convenient temperatures. Read moreRead less
Lived experiences of treatment for hepatitis C in Australia. This project aims to support uptake of new hepatitis C treatments. With the introduction of new treatments in 2016, the Australian Government adopted the WHO’s goal of eliminating the disease by 2030. While early treatment rates were high, they have since plateaued, with stigma and poor information considered key obstacles. This project will generate new knowledge on treatment decisions and experiences, using a proven qualitative metho ....Lived experiences of treatment for hepatitis C in Australia. This project aims to support uptake of new hepatitis C treatments. With the introduction of new treatments in 2016, the Australian Government adopted the WHO’s goal of eliminating the disease by 2030. While early treatment rates were high, they have since plateaued, with stigma and poor information considered key obstacles. This project will generate new knowledge on treatment decisions and experiences, using a proven qualitative methodology. In doing so, it will produce a website covering personal experiences of treatment, issues in treatment decision-making, and advice on enhancing life on treatment and after. It will tackle hepatitis C-related stigma, and inform and benefit potential treatment users, families and relevant professionals.
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Who’s who in the plant gene world? As many more plant genomes are sequenced, the bottleneck is being able to interrogate and translate this data into applications for crop improvement. This project will develop and apply a population graph database, hosting genome data for the world’s major crops and their wild relatives, allowing the characterisation of gene diversity on an unparalleled scale. Analysis of this data will reveal the presence/absence and sequence diversity for classes of genes for ....Who’s who in the plant gene world? As many more plant genomes are sequenced, the bottleneck is being able to interrogate and translate this data into applications for crop improvement. This project will develop and apply a population graph database, hosting genome data for the world’s major crops and their wild relatives, allowing the characterisation of gene diversity on an unparalleled scale. Analysis of this data will reveal the presence/absence and sequence diversity for classes of genes for important agronomic traits including disease resistance, flowering time and legume nitrogen fixation which will enable plant breeders to identify and apply novel genes and allelic variants for use in breeding programmes, accelerating the production of improved crop varieties.Read moreRead less
Electron, positron, and heavy-particle collisions with molecules. This project aims to develop a computational approach to collisions involving molecular targets with electrons, positrons and heavy particles. Recently, the approach to atomic collisions, the Convergent Close Coupling (CCC) method, has been extended and verified for positron, electron, and heavy particle collisions with the simplest molecular systems (molecular hydrogen and its ion). This project now aims to extend the CCC method ....Electron, positron, and heavy-particle collisions with molecules. This project aims to develop a computational approach to collisions involving molecular targets with electrons, positrons and heavy particles. Recently, the approach to atomic collisions, the Convergent Close Coupling (CCC) method, has been extended and verified for positron, electron, and heavy particle collisions with the simplest molecular systems (molecular hydrogen and its ion). This project now aims to extend the CCC method to study collisions with more complex molecules. Expected benefits include more accurate data for diagnostic tools such as Positron Emission Tomography, and potential advances in particle-based cancer therapy.Read moreRead less