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.
In search of the origin of mass at the Large Hadron Collider. This project will utilise new theoretical ideas and worldwide experimental efforts at the Large Hadron Collider with the aim to resolve one of the most profound mysteries of modern physics, the origin of mass in the universe. The results will have an important longstanding impact by promoting innovation culture and public education of science.
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
High productivity of hybrid plasma electrocatalytic fertiliser production. Non-thermal plasma-driven electrocatalytic production of nitrogen fertilisers. The project aims to develop scalable technology for ambient production of fertilisers using renewable energy, air, water, and captured CO2. This project is anticipated to generate new knowledge in plasma catalysis and electrochemical coupling through designing and fine-tuning catalyst-loaded 3D scaffolds. Expected outcomes of this project inclu ....High productivity of hybrid plasma electrocatalytic fertiliser production. Non-thermal plasma-driven electrocatalytic production of nitrogen fertilisers. The project aims to develop scalable technology for ambient production of fertilisers using renewable energy, air, water, and captured CO2. This project is anticipated to generate new knowledge in plasma catalysis and electrochemical coupling through designing and fine-tuning catalyst-loaded 3D scaffolds. Expected outcomes of this project include increasing the capacity to adopt low-cost and decentralised methods for renewable energy utilisation. This should provide substantial technological capacity that can be applied to other sectors of Australia's developing hydrogen economy and expand the use of renewable energy Power-to-X for zero-emissions energy vectors.Read moreRead less
Wave energy transport, conversion and dissipation in near-Earth space. The near-Earth space environment is characterised by cycles of energy transport, conversion and release through particle acceleration that lead to dazzling aurora and damaged spacecraft and communication systems. This research seeks to identify how this energy is transported through space and the means through which it is converted and released.
Nanoscale control of energy and matter for future energy-efficient technologies. Unprecedented control of energy and matter in nanoscale fabrication will be achieved using non-equilibrium self-organised plasma-solid systems. The outcomes will lead to energy-efficient, environment- and human-health-friendly production of nanomaterials for future energy, health, information, food, water, environmental and security technologies.