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Harnessing vacuum forces for quantum sensing of graphene motion

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arxiv 1304.8090 v2 pith:KG65MKY4 submitted 2013-04-30 quant-ph cond-mat.mes-hall

Harnessing vacuum forces for quantum sensing of graphene motion

classification quant-ph cond-mat.mes-hall
keywords graphenequantummechanicalstrongemittermanymethodsoptical
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Position measurements at the quantum level are vital for many applications, but also challenging. Typically, methods based on optical phase shifts are used, but these methods are often weak and difficult to apply to many materials. An important example is graphene, which is an excellent mechanical resonator due to its small mass and an outstanding platform for nanotechnologies, but is largely transparent. Here, we present a novel detection scheme based upon the strong, dispersive vacuum interactions between a graphene sheet and a quantum emitter. In particular, the mechanical displacement causes strong changes in the vacuum-induced shifts of the transition frequency of the emitter, which can be read out via optical fields. We show that this enables strong quantum squeezing of the graphene position on time scales short compared to the mechanical period.

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