Resonant interaction of trapped cold atoms with a magnetic cantilever tip | Zendy

Cris Montoya | Zendy; J. L. Valencia | Zendy; Andrew Geraci | Zendy; Matthew Eardley | Zendy; John Moreland | Zendy; L. Hollberg | Zendy; John Kitching | Zendy

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Resonant interaction of trapped cold atoms with a magnetic cantilever tip

Author(s) -

Cris Montoya,

J. L. Valencia,

Andrew Geraci,

Matthew Eardley,

John Moreland,

L. Hollberg,

John Kitching

Publication year - 2015

Publication title -

physical review a

Language(s) - English

Resource type - Journals

eISSN - 1094-1622

pISSN - 1050-2947

DOI - 10.1103/physreva.91.063835

Subject(s) - physics , zeeman effect , cantilever , spins , atomic physics , excited state , magnetic field , coupling (piping) , condensed matter physics , materials science , quantum mechanics , metallurgy , composite material

Magnetic resonance in an ensemble of laser-cooled trapped Rb atoms is excited using a micro- cantilever with a magnetic tip. The cantilever is mounted on a multi-layer chip designed to capture, cool, and magnetically transport cold atoms. The coupling is observed by measuring the loss from a magnetic trap as the oscillating cantilever induces Zeeman state transitions in the atoms. Interfacing cold atoms with mechanical devices could enable probing and manipulating atomic spins with nanometer spatial resolution and single-spin sensitivity, leading to new capabilities in quantum computation, quantum simulation, or precision sensing.

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