Utilizing weak pump depletion to stabilize squeezed vacuum states

T. Denker; D. Schütte; M. H. Wimmer; T. A. Wheatley; E. H. Huntington; M. Heurs

doi:10.1364/OE.23.016517

Utilizing weak pump depletion to stabilize squeezed vacuum states

T. Denker, D. Schütte, M. H. Wimmer, T. A. Wheatley, E. H. Huntington, M. Heurs

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Abstract

We propose and demonstrate a pump-phase locking technique that makes use of weak pump depletion (WPD) - an unavoidable effect that is usually neglected - in a sub-threshold optical parametric oscillator (OPO). We show that the phase difference between seed and pump beam is imprinted on both light fields by the non-linear interaction in the crystal and can be read out without disturbing the squeezed output. In our experimental setup we observe squeezing levels of 1.96±0.01 dB, with an anti-squeezing level of 3.78±0.02dB (for a 0.55mW seed beam at 1064nm and 67.8 mW of pump light at 532 nm). Our new locking technique allows for the first experimental realization of a pump-phase lock by reading out the pre-existing phase information in the pump field. There is no degradation of the detected squeezed states required to implement this scheme.

Original language	English
Pages (from-to)	16517-16528
Number of pages	12
Journal	Optics Express
Volume	23
Issue number	13
DOIs	https://doi.org/10.1364/OE.23.016517
Publication status	Published - 29 Jun 2015

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title = "Utilizing weak pump depletion to stabilize squeezed vacuum states",

abstract = "We propose and demonstrate a pump-phase locking technique that makes use of weak pump depletion (WPD) - an unavoidable effect that is usually neglected - in a sub-threshold optical parametric oscillator (OPO). We show that the phase difference between seed and pump beam is imprinted on both light fields by the non-linear interaction in the crystal and can be read out without disturbing the squeezed output. In our experimental setup we observe squeezing levels of 1.96±0.01 dB, with an anti-squeezing level of 3.78±0.02dB (for a 0.55mW seed beam at 1064nm and 67.8 mW of pump light at 532 nm). Our new locking technique allows for the first experimental realization of a pump-phase lock by reading out the pre-existing phase information in the pump field. There is no degradation of the detected squeezed states required to implement this scheme.",

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AU - Denker, T.

AU - Schütte, D.

AU - Wimmer, M. H.

AU - Wheatley, T. A.

AU - Huntington, E. H.

AU - Heurs, M.

PY - 2015/6/29

Y1 - 2015/6/29

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Utilizing weak pump depletion to stabilize squeezed vacuum states

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