Atomic physics on a 50-nm scale: Realization of a bilayer system of dipolar atoms

Du, Li; Barral, Pierre; Cantara, Michael; de Hond, Julius; Lu, Yu-Kun; Ketterle, Wolfgang

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Du, Li; Barral, Pierre; Cantara, Michael; de Hond, Julius; Lu, Yu-Kun; ... Show more

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Abstract

Controlling ultracold atoms with laser light has greatly advanced quantum science. The wavelength of light sets a typical length scale for most experiments to the order of 500 nanometers (nm) or greater. In this work, we implemented a super-resolution technique that localizes and arranges atoms on a sub–50-nm scale, without any fundamental limit in resolution. We demonstrate this technique by creating a bilayer of dysprosium atoms and observing dipolar interactions between two physically separated layers through interlayer sympathetic cooling and coupled collective excitations. At 50-nm distance, dipolar interactions are 1000 times stronger than at 500 nm. For two atoms in optical tweezers, this should enable purely magnetic dipolar gates with kilohertz speed.

Date issued

2024-05-02

URI

https://hdl.handle.net/1721.1/154380

Department

MIT-Harvard Center for Ultracold Atoms; Massachusetts Institute of Technology. Department of Physics

Journal

Science

Publisher

American Association for the Advancement of Science

Citation

Du, Li, Barral, Pierre, Cantara, Michael, de Hond, Julius, Lu, Yu-Kun et al. 2024. "Atomic physics on a 50-nm scale: Realization of a bilayer system of dipolar atoms." Science.

Version: Author's final manuscript

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