物理
光子
腔量子电动力学
谐振器
量子位元
背景(考古学)
材料科学
联轴节(管道)
量子技术
量子光学
量子
光学腔
光电子学
量子退相干
量子力学
开放量子系统
激光器
量子电动力学
生物
古生物学
冶金
作者
Simon Gröblacher,Klemens Hammerer,Michael R. Vanner,Markus Aspelmeyer
出处
期刊:Nature
[Nature Portfolio]
日期:2009-08-01
卷期号:460 (7256): 724-727
被引量:964
摘要
Achieving coherent quantum control over massive mechanical resonators is a current research goal. Nano- and micromechanical devices can be coupled to a variety of systems, for example to single electrons by electrostatic or magnetic coupling, and to photons by radiation pressure or optical dipole forces. So far, all such experiments have operated in a regime of weak coupling, in which reversible energy exchange between the mechanical device and its coupled partner is suppressed by fast decoherence of the individual systems to their local environments. Controlled quantum experiments are in principle not possible in such a regime, but instead require strong coupling. So far, this has been demonstrated only between microscopic quantum systems, such as atoms and photons (in the context of cavity quantum electrodynamics) or solid state qubits and photons. Strong coupling is an essential requirement for the preparation of mechanical quantum states, such as squeezed or entangled states, and also for using mechanical resonators in the context of quantum information processing, for example, as quantum transducers. Here we report the observation of optomechanical normal mode splitting, which provides unambiguous evidence for strong coupling of cavity photons to a mechanical resonator. This paves the way towards full quantum optical control of nano- and micromechanical devices.
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