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Performance and limits of feedback cooling methods for levitated oscillators: A direct comparison

T. W. Penny, A. Pontin, P. F. Barker

2021Physical review. A/Physical review, A22 citationsDOIOpen Access PDF

Abstract

Cooling the center-of-mass motion is an important tool for levitated optomechanical systems, but it is often not clear which method can practically reach lower temperatures for a particular experiment. We directly compare the parametric and velocity feedback damping methods, which are used extensively for cooling the motion of single trapped particles in a range of traps. By performing experiments on the same particle, and with the same detection system, we demonstrate that velocity damping cools the oscillator to a temperature an order of magnitude lower and is more resilient to imperfect experimental conditions. We show that these results are consistent with analytical limits as well as numerical simulations that include experimental noise.

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PhysicsRange (aeronautics)Parametric statisticsNoise (video)MechanicsControl theory (sociology)Particle (ecology)Computer scienceAerospace engineeringEngineeringMathematicsControl (management)OceanographyStatisticsImage (mathematics)GeologyArtificial intelligenceMechanical and Optical ResonatorsQuantum Electrodynamics and Casimir EffectExperimental and Theoretical Physics Studies
Performance and limits of feedback cooling methods for levitated oscillators: A direct comparison | Litcius