GEO600 beam splitter thermal compensation system: new design and commissioning

arXiv - PHYS - Instrumentation and Detectors Pub Date : 2024-08-05 DOI:arxiv-2408.02804

Séverin Nadji, Holger Wittel, Nikhil Mukund, James Lough, Christoph Affeldt, Fabio Bergamin, Marc Brinkmann, Volker Kringel, Harald Lück, Michael Weinert, Karsten Danzmann

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Abstract

Gravitational waves have revolutionised the field of astronomy by providing scientists with a new way to observe the universe and gain a better understanding of exotic objects like black holes. Several large-scale laser interferometric gravitational wave detectors (GWDs) have been constructed worldwide, with a focus on achieving the best sensitivity possible. However, in order for a detector to operate at its intended sensitivity, its optics must be free from imperfections such as thermal lensing effects. In the GEO\,600 gravitational wave detector, the beam splitter (BS) experiences a significant thermal lensing effect due to the high power build-up in the Power Recycling Cavity (PRC) combined with a very small beam waist. This causes the fundamental mode to be converted into higher order modes (HOMs), subsequently impacting the detector's performance. To address this issue, the GEO\,600 detector is equipped with a thermal compensation system (TCS) applied to the BS. This involves projecting a spatially tunable heating pattern through an optical system onto the beam splitter. The main objective of the TCS is to counteract the thermal lens at the BS and restore the detector to its ideal operating condition. This paper presents the new beam splitter TCS in GEO\,600, its commissioning, and its effect on strain sensitivity. It also outlines the planned upgrade to further enhance the performance of the TCS.

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GEO600 分光镜热补偿系统：新设计和调试

引力波为科学家提供了一种观测宇宙和更好地了解黑洞等奇异天体的新方法，从而彻底改变了天文学领域。世界范围内已经建造了多个大型激光干涉引力波探测器（GWDs），重点是尽可能实现最佳灵敏度。然而，为了使探测器以预期的灵敏度运行，其光学系统必须避免热透镜效应等缺陷。在 GEO\600 重力波探测器中，由于功率再循环腔（PRC）中的高功率积聚和极小的束腰，分光器（BS）经历了显著的热透镜效应。这会导致基模转换为高阶模（HOM），从而影响探测器的性能。为了解决这个问题，GEO\600 探测器配备了应用于 BS 的热补偿系统（TCS）。这包括通过光学系统将空间可调的加热模式投射到分光器上。热补偿系统的主要目的是抵消 BS 上的热透镜，使探测器恢复到理想的工作状态。本文介绍了 GEO\600 中的新型分光镜 TCS、其调试情况及其对应变灵敏度的影响。它还概述了为进一步提高分束器性能而计划进行的升级。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Instrumentation and Detectors

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