Cavity optomechanics has achieved the major breakthrough of the preparation and observation of macroscopic mechanical oscillators in non-classical states. The development of reliable indicators of the oscillator properties in these conditions is important also for applications to quantum technologies. We compare two procedures to infer the oscillator occupation number, minimizing the necessity of system calibrations. The former starts from homodyne spectra, the latter is based on the measurement of the motional sideband asymmetry in heterodyne spectra. Moreover, we describe and discuss a method to control the cavity detuning, that is a crucial parameter for the accuracy of the latter, intrinsically superior procedure.
Calibrated quantum thermometry in cavity optomechanics / Chowdhury, A; Vezio, P; Bonaldi, M; Borrielli, A; Marino, F; Morana, B; Pandraud, G; Pontin, A; Prodi, G A; Sarro, P M; Serra, E; Marin, F. - In: QUANTUM SCIENCE AND TECHNOLOGY. - ISSN 2058-9565. - STAMPA. - 4:(2019), pp. 024007-024007. [10.1088/2058-9565/ab05f1]
Calibrated quantum thermometry in cavity optomechanics
Vezio, P;Marino, F;Pontin, A;Marin, F
2019
Abstract
Cavity optomechanics has achieved the major breakthrough of the preparation and observation of macroscopic mechanical oscillators in non-classical states. The development of reliable indicators of the oscillator properties in these conditions is important also for applications to quantum technologies. We compare two procedures to infer the oscillator occupation number, minimizing the necessity of system calibrations. The former starts from homodyne spectra, the latter is based on the measurement of the motional sideband asymmetry in heterodyne spectra. Moreover, we describe and discuss a method to control the cavity detuning, that is a crucial parameter for the accuracy of the latter, intrinsically superior procedure.I documenti in FLORE sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.