Frequency-Dependent Squeezing from a Detuned Squeezer
J. Junker, Dennis Wilken, Nived Johny, Daniel Steinmeyer, M. Heurs
Abstract
Frequency-dependent squeezing is a promising technique to overcome the standard quantum limit in optomechanical force measurements, e.g., gravitational wave detectors. For the first time, we show that frequency-dependent squeezing can be produced by detuning an optical parametric oscillator from resonance. Its frequency-dependent Wigner function is reconstructed quantum tomographically and exhibits a rotation by 39°, along which the noise is reduced by up to 5.5 dB. Our setup is suitable for realizing effective negative-mass oscillators required for coherent quantum noise cancellation.
Topics & Concepts
PhysicsNoise (video)Quantum noiseSqueezed coherent stateQuantumWigner distribution functionParametric oscillatorQuantum opticsQuantum limitOptical parametric oscillatorLimit (mathematics)Quantum mechanicsRotation (mathematics)Coherent statesLaserMathematicsMathematical analysisGeometryArtificial intelligenceComputer scienceImage (mathematics)Mechanical and Optical ResonatorsGeophysics and Sensor TechnologyAdvanced MEMS and NEMS Technologies