Minimally destructive, Doppler measurement of a quantized flow in a ring-shaped Bose–Einstein condensate

Minimally destructive, Doppler measurement of a quantized flow in a ring-shaped Bose–Einstein condensate

The Doppler effect, the shift in the frequency of sound due to motion, is present in both classical gases and quantum superfluids. Here, we perform an in situ , minimally destructive measurement, of the persistent current in a ring-shaped, superfluid Bose–Einstein condensate using the Doppler effect...

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Bibliographic Details
Main Authors: A Kumar, N Anderson, W D Phillips, S Eckel, G K Campbell, S Stringari
Format: Article
Language:English
Published: IOP Publishing 2016-01-01
Series:New Journal of Physics
Subjects:
atomtronic devices
persistent currents
superfluidity
Online Access:https://doi.org/10.1088/1367-2630/18/2/025001
Description
Summary:The Doppler effect, the shift in the frequency of sound due to motion, is present in both classical gases and quantum superfluids. Here, we perform an in situ , minimally destructive measurement, of the persistent current in a ring-shaped, superfluid Bose–Einstein condensate using the Doppler effect. Phonon modes generated in this condensate have their frequencies Doppler shifted by a persistent current. This frequency shift will cause a standing-wave phonon mode to be ‘dragged’ along with the persistent current. By measuring this precession, one can extract the background flow velocity. This technique will find utility in experiments where the winding number is important, such as in emerging ‘atomtronic’ devices.
ISSN:1367-2630

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