A high flux continuous atom laser. This project aims to create an unprecedented ultra-cold atom source - a high brightness continuous atom laser. Such a device, the atomic analogue of an optical laser, may find near term application in precision inertial sensing based on atom interferometry. The proposed apparatus will utilise new techniques in cutting edge laser cooling and continuous all-optical wave-guiding to dramatically boost the density, collision rate and flux in a guided system. It is e ....A high flux continuous atom laser. This project aims to create an unprecedented ultra-cold atom source - a high brightness continuous atom laser. Such a device, the atomic analogue of an optical laser, may find near term application in precision inertial sensing based on atom interferometry. The proposed apparatus will utilise new techniques in cutting edge laser cooling and continuous all-optical wave-guiding to dramatically boost the density, collision rate and flux in a guided system. It is expected that the project will allow the study of previously unexplored territory in ultra-cold atom atomic physics.Read moreRead less
Creating high flux degenerate quantum atomic sources with active feedback. This project aims to deliver a new technique for cooling dilute ultracold gases, which are rapidly transitioning from a fundamental physics platform to a building block for quantum technology. This technique is measurement-based feedback cooling. Unlike the current evaporative methods, feedback cooling neither loses atoms, nor relies on elastic collisions or internal atomic structure. This opens up the possibility of dire ....Creating high flux degenerate quantum atomic sources with active feedback. This project aims to deliver a new technique for cooling dilute ultracold gases, which are rapidly transitioning from a fundamental physics platform to a building block for quantum technology. This technique is measurement-based feedback cooling. Unlike the current evaporative methods, feedback cooling neither loses atoms, nor relies on elastic collisions or internal atomic structure. This opens up the possibility of directly cooling traditionally un-coolable systems. This project will expand the quality and range of available atomic sources, benefitting research into exotic materials, and improving precision sensor applications. Quantum sensors are rapidly reforming our image of what a sensor is and what it can do, offering unprecedented opportunities in sensor fusion, and directly impacting business opportunities in mineral exploration, mapping and navigation.Read moreRead less