非平衡Michelson-Sagnac干涉仪中增强的光-力相互作用

Alexandr Karpenko, Mikhail Korobko, Sergey P. Vyatchanin
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引用次数: 0

摘要

量子光力学系统使研究大质量物体的量子性质的基本问题成为可能。为此,需要光和机械运动之间的强耦合,这对大质量物体提出了挑战。特别是,具有低频振荡器的大型干涉传感器很难引入量子状态。本文提出了在Michelson-Sagnac干涉仪中不平衡中央分束器,与平衡分束器相比,这使我们能够提高光机械耦合强度。这种不平衡使我们能够增强系统中存在的两种类型的光-机械耦合的合作作用:耗散和色散。我们分析了两种不同的光机械腔结构,即由激光泵浦场反射镜(功率回收)和信号场反射镜(信号回收)组成的光机械腔。我们表明,分束器的不平衡使我们能够显著地增加测试质量运动的光学冷却。我们还给出了观测量子辐射压力噪声和有源压缩的条件。我们的结构可以作为对干涉仪进行更复杂修改的基础,以利用增强的耦合强度。这将使我们能够有效地达到大测试质量的量子态,为研究量子力学的基本方面和量子引力的实验研究开辟了道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Enhanced optomechanical interaction in an unbalanced Michelson-Sagnac interferometer
Quantum optomechanical systems enable the study of fundamental questions on the quantum nature of massive objects. For that a strong coupling between light and mechanical motion is required, which presents a challenge for massive objects. In particular, large interferometric sensors with low-frequency oscillators are difficult to bring into the quantum regime. Here we propose unbalancing the central beam splitter in the Michelson-Sagnac interferometer, which allows us to boost the optomechanical coupling strength compared with a balanced beam splitter. This unbalancing allows us to enhance the cooperative action of two types of optomechanical coupling present in the system: dissipative and dispersive. We analyze two different configurations, in which the optomechanical cavity is formed by the mirror for the laser pump field (power recycling) and by the mirror for the signal field (signal recycling). We show that the imbalance of the beam splitter allows us to dramatically increase the optical cooling of the test-mass motion. We also formulate the conditions for observing quantum radiation-pressure noise and ponderomotive squeezing. Our configuration could serve as the basis for more complex modifications of the interferometer that would utilize the enhanced coupling strength. This would allow us to efficiently reach the quantum state of large test masses, opening the way to studying the fundamental aspects of quantum mechanics and the experimental search for quantum gravity.
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