http://arxiv.org/abs/2203.03849
Squeezed vacuum states are now employed in gravitational-wave interferometric detectors, en- hancing their sensitivity and thus enabling richer astrophysical observations. In future observing runs, the detectors will incorporate a filter cavity to suppress quantum radiation pressure noise using frequency-dependent squeezing. Interferometers employing internal and external cavities de- cohere and degrade squeezing in complex new ways, which must be studied to achieve increasingly ambitious noise goals. This paper introduces an audio diagnostic field (ADF) to quickly and ac- curately characterize the frequency-dependent response and the transient perturbations of resonant optical systems to squeezed states. This analysis enables audio field injections to become a powerful tool to witness and optimize interactions such as inter-cavity mode matching within gravitational- wave instruments. To demonstrate, we present experimental results from using the audio field to characterize a 16 m prototype filter cavity.
D. Ganapathy, V. Xu, W. Jia, et. al.
Wed, 9 Mar 22
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