We describe an experiment achieving radiation pressure excitation and cooling of a mechanical mode in a cryogenic Fabry-Perot cavity with a micromechanical oscillator [micro-electro-mechanical systems (MEMS)] as end mirror. The response function to periodic modulations of the intracavity power provides an independent measurement of the effective modal mass allowing an accurate estimate of the mode temperature from the corresponding displacement noise spectrum. We also obtained optical cooling of the MEMS fundamental mode at 110 kHz from 11 to 4.4 K, limited only by the optical Finesse and the mechanical quality of the system. These results represent a step toward the observation of quantum optomechanical effects and motivate further experiments with improved performances of the MEMS samples.
Radiation pressure excitation and cooling of a cryogenic micro-mechanical systems cavity
Marino F;D'Arrigo G;Cataliotti FS;
2009
Abstract
We describe an experiment achieving radiation pressure excitation and cooling of a mechanical mode in a cryogenic Fabry-Perot cavity with a micromechanical oscillator [micro-electro-mechanical systems (MEMS)] as end mirror. The response function to periodic modulations of the intracavity power provides an independent measurement of the effective modal mass allowing an accurate estimate of the mode temperature from the corresponding displacement noise spectrum. We also obtained optical cooling of the MEMS fundamental mode at 110 kHz from 11 to 4.4 K, limited only by the optical Finesse and the mechanical quality of the system. These results represent a step toward the observation of quantum optomechanical effects and motivate further experiments with improved performances of the MEMS samples.File | Dimensione | Formato | |
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