{"id":655,"date":"2021-06-28T12:22:51","date_gmt":"2021-06-28T12:22:51","guid":{"rendered":"https:\/\/www.matterwaveoptics.eu\/?p=655"},"modified":"2021-06-29T15:05:25","modified_gmt":"2021-06-29T15:05:25","slug":"biagioni-giulio-rotation-of-a-dipolar-supersolid","status":"publish","type":"post","link":"https:\/\/www.matterwaveoptics.eu\/FOMO2022\/fomo2021\/contributed-talks\/fomo2021-abstract\/biagioni-giulio-rotation-of-a-dipolar-supersolid\/","title":{"rendered":"Biagioni, Giulio — Rotation of a dipolar supersolid"},"content":{"rendered":"\n

Supersolids are a fundamental state of matter in which the same atoms that form a crystalline lattice are also responsible for the coherent flow of mass, typical of superfluids. In 2018, my group realized for the first time a supersolid phase in a quantum gas of strongly dipolar atoms. During the talk, I will focus on our latest work, in which we measure the moment of inertia of the dipolar supersolid [1]. We find that the moment of inertia of the supersolid is lower than the classical value, although the crystalline structure increases the moment of inertia compared to that of a standard superfluid. Our measurement directly demonstrates the superfluid nature of the dipolar supersolid with a rotational experiment and adds the supersolid to the list of superfluid systems with a quenched moment of inertia. <\/p>\n\n\n\n

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