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Cooling a mechanical resonator with nitrogen-vacancy centres using a room temperature excited state spin–strain interaction

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  • E. R. MacQuarrie

    (Cornell University)

  • M. Otten

    (Cornell University)

  • S. K. Gray

    (Center for Nanoscale Materials, Argonne National Laboratory)

  • G. D. Fuchs

    (School of Applied and Engineering Physics, Cornell University)

Abstract

Cooling a mechanical resonator mode to a sub-thermal state has been a long-standing challenge in physics. This pursuit has recently found traction in the field of optomechanics in which a mechanical mode is coupled to an optical cavity. An alternate method is to couple the resonator to a well-controlled two-level system. Here we propose a protocol to dissipatively cool a room temperature mechanical resonator using a nitrogen-vacancy centre ensemble. The spin ensemble is coupled to the resonator through its orbitally-averaged excited state, which has a spin–strain interaction that has not been previously studied. We experimentally demonstrate that the spin–strain coupling in the excited state is 13.5±0.5 times stronger than the ground state spin–strain coupling. We then theoretically show that this interaction, combined with a high-density spin ensemble, enables the cooling of a mechanical resonator from room temperature to a fraction of its thermal phonon occupancy.

Suggested Citation

  • E. R. MacQuarrie & M. Otten & S. K. Gray & G. D. Fuchs, 2017. "Cooling a mechanical resonator with nitrogen-vacancy centres using a room temperature excited state spin–strain interaction," Nature Communications, Nature, vol. 8(1), pages 1-10, April.
    • Handle: RePEc:nat:natcom:v:8:y:2017:i:1:d:10.1038_ncomms14358
    DOI: 10.1038/ncomms14358
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