Big time crystals: a new paradigm in condensed matter. This project aims to extend condensed matter physics to the time dimension using big time crystals created by a periodically driven Bose-Einstein condensate. Such a system is expected to offer exceptional versatility, allowing effective potentials and long-range interactions in a time lattice to be engineered almost at will by proper periodic driving and modulation of the particle interaction. Expected outcomes include realisation of novel c ....Big time crystals: a new paradigm in condensed matter. This project aims to extend condensed matter physics to the time dimension using big time crystals created by a periodically driven Bose-Einstein condensate. Such a system is expected to offer exceptional versatility, allowing effective potentials and long-range interactions in a time lattice to be engineered almost at will by proper periodic driving and modulation of the particle interaction. Expected outcomes include realisation of novel condensed matter phenomena such as topologically protected states in the time dimension, time crystalline structures exhibiting disorder or quasi-crystalline order and time-tronics devices analogous to electronics. Potential future benefits include novel advanced materials and semiconductor-like devices. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100183
Funder
Australian Research Council
Funding Amount
$377,429.00
Summary
Understanding the birth of new elements by observing dying stars. Almost everything around us is made up of elements that were created inside stars. This project aims to understand the origin of the elements by studying newly created material ejected by Sun-like stars during one of the final stages of their lives. This project expects to generate new knowledge in the field of stellar evolution by using state-of-the-art telescopes to measure the elements and isotopes produced by these stars and c ....Understanding the birth of new elements by observing dying stars. Almost everything around us is made up of elements that were created inside stars. This project aims to understand the origin of the elements by studying newly created material ejected by Sun-like stars during one of the final stages of their lives. This project expects to generate new knowledge in the field of stellar evolution by using state-of-the-art telescopes to measure the elements and isotopes produced by these stars and comparing them with theoretical model predictions. Expected outcomes include a better understanding of element creation, the chemical enrichment of galaxies, and the first mass estimates for intermediate-mass stars. This should provide significant benefits by addressing a key outstanding question in astronomy.Read moreRead less