Titlebook: Cavity Optomechanics; Nano- and Micromecha Markus Aspelmeyer,Tobias J. Kippenberg,Florian Mar Book 2014 Springer-Verlag Berlin Heidelberg 2

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https://doi.org/10.1007/978-3-8349-9803-3, the field also benefited from the advances of nanophotonics. We discuss here the merits of Gallium Arsenide (GaAs) optomechanical disk resonators, which bring together high mechanical frequency, ultra-strong optomechanical coupling and low optical/mechanical dissipation. Based on a relatively simp

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Aktuelle Entwicklungslinien der OMU-Theorie,d by light on dielectrics and the photoelastic scattering of light from an acoustic wave. We first provide a review of the phenomenon and continue with the first experiments where stimulated Brillouin optomechanical actuation was used in microdevices, and spontaneous Brillouin cooling was demonstrat

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https://doi.org/10.1007/978-3-8349-9803-3e control. This chapter discusses further integration of chip-scale optomechanic elements on a circuit level. Circuit integrated optomechanics brings a range of additional benefits for both fundamental studies and practical device applications of optomechanics. It takes advantage of many circuit com

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Comparative Institutional Analysis,ructure was cooled in a dilution refrigerator to .?mK. The resonator had a fundamental dilatational resonance frequency in excess of 6?GHz, so once cooled to this temperature, the number of thermal phonons at this frequency is vanishingly small. This achievement is a direct consequence of the high r

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https://doi.org/10.1007/978-3-8349-9865-1ate spin qubits, or superconducting devices. We summarize and compare different coupling schemes and describe first experimental implementations. Hybrid mechanical systems enable new approaches to quantum control of mechanical objects, precision sensing, and quantum information processing.