Title :
Ultralow dissipation optomechanical resonators on a chip
Author :
Anetsberger, G. ; Riviere, R. ; Schliesser, A. ; Arcizet, O. ; Kippenberg, T.J.
Author_Institution :
Max-Planck-Inst. fur Quantenopt., Garching, Germany
Abstract :
This work shows independent control over both optical and mechanical degrees of freedom in the microscale optomechanical resonator. Studying the dissipation of different mechanical modes of silica microtoroids it was possible to directly observe mechanical normal mode splitting between different modes of a micromechanical system. The fundamental radial breathing mode (RBM) can couple to flexural modes giving rise to avoided crossings. For the RBM this hybridization with low-Q flexural modes entails enhanced losses due to excitation of acoustic waves at the clamping region. This loss can be accurately modelled using finite element simulation which has then been employed to devise novel resonators with unprecedentedly low mechanical losses as described below.
Keywords :
finite element analysis; micro-optomechanical devices; micromechanical resonators; optical control; silicon compounds; avoided crossings; dissipation; finite element simulation; flexural modes; micromechanical system; normal mode splitting; optomechanical resonators; radial breathing mode; silica microtoroids; Clamps; Frequency; Microcavities; Optical control; Optical design; Optical losses; Optical resonators; Oscillators; Q factor; Silicon compounds;
Conference_Titel :
Lasers and Electro-Optics 2009 and the European Quantum Electronics Conference. CLEO Europe - EQEC 2009. European Conference on
Conference_Location :
Munich
Print_ISBN :
978-1-4244-4079-5
Electronic_ISBN :
978-1-4244-4080-1
DOI :
10.1109/CLEOE-EQEC.2009.5192612
