Robust squeezed light against mode mismatch using a self imaging optical parametric oscillator

Abstract: We present squeezed light that is robust against spatial mode mismatch (beam displacement, tilt, and beam-size difference), which is generated from a self-imaging optical parametric oscillator below the threshold. We investigate the quantum properties of the generated light when the oscillator is detuned from the ideal self-imaging condition for stable operation. We find that the generated light is more robust to mode mismatch than single-mode squeezed light having the same squeezing level, and it even outperf… Show more

“…In other words, the spatial squeezing is homogeneous in the probe regime. This is in contrast to the case of single-mode squeezing where the observed squeezing will be degraded considerably for increasing mode mismatch [40][41][42][43]. The squeezing decreases from −15.33 dB at w L /w p = 1 to around −1.51 dB at w L /w p = 0.01, suggesting localized squeezing at ∼10 2 μm 2 and alternatively 10 4 of spatially squeezed modes in the probe regime which is of an area 1 mm 2 .…”

Quadrature squeezing of 10 4 spatial modes via manipulation of diffraction

“…In other words, the spatial squeezing is homogeneous in the probe regime. This is in contrast to the case of single-mode squeezing where the observed squeezing will be degraded considerably for increasing mode mismatch [40][41][42][43]. The squeezing decreases from −15.33 dB at w L /w p = 1 to around −1.51 dB at w L /w p = 0.01, suggesting localized squeezing at ∼10 2 μm 2 and alternatively 10 4 of spatially squeezed modes in the probe regime which is of an area 1 mm 2 .…”

Quadrature squeezing of 10 4 spatial modes via manipulation of diffraction

10 dB Quantum-Enhanced Michelson Interferometer with Balanced Homodyne Detection

Modes mismatch induced variation of quantum coherence for two-mode localized Gaussian states in accelerated frame