{"id":612,"date":"2021-06-27T18:54:09","date_gmt":"2021-06-27T18:54:09","guid":{"rendered":"https:\/\/www.matterwaveoptics.eu\/?p=612"},"modified":"2021-06-27T18:54:13","modified_gmt":"2021-06-27T18:54:13","slug":"bandarupally-satvika-atom-interferometry-based-on-narrow-linewidth-transitions-in-sr-and-cd","status":"publish","type":"post","link":"https:\/\/www.matterwaveoptics.eu\/FOMO2022\/fomo2021\/contributed-talks\/fomo2021-abstract\/bandarupally-satvika-atom-interferometry-based-on-narrow-linewidth-transitions-in-sr-and-cd\/","title":{"rendered":"Bandarupally, Satvika — Atom Interferometry based on narrow linewidth transitions in Sr and Cd"},"content":{"rendered":"\n

Atom interferometers with their extremely high sensitivity to inertial forces are an excellent method for investigating and understanding gravity and its gradi- ents. Due to the lack of a unified theory which puts the quantum mechanical nature of the world along with gravitational interactions (best explained by gen- eral relativity), studying gravity using quantum mechanical test sources, such as ultra-cold atoms, is an exciting choice for probing physics at this intersec- tion. In this brief talk, I will discuss work towards the realization of novel atom interferometers based upon Sr and Cd atoms, which posses a common electronic structure with two valence electrons, which provides access to narrow linewidth intercombination transitions. For these experiments, a novel high- power, tunable, narrow-linewidth VECSEL source has been developed, which acts as a master source to produce continuous light at either 461 nm or 229 nm, corresponding to the cooling transitions in Sr and Cd atoms, respectively.<\/p>\n\n\n\n

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