Adaptive optics methods in gravitational wave interferometric detectors, a perspective

Proceedings of Gravitational-waves Science&Technology Symposium — PoS(GRASS2018) Pub Date : 2018-09-17 DOI:10.22323/1.325.0008

M. Lorenzini, L. Aiello, E. Cesarini, V. Fafone, D. Lumaca, Y. Minenkov, I. Nardecchia, A. Rocchi, V. Sequino

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Abstract

The performance of present and future gravitational wave detectors is limited by fundamental factors, such as thermal noise, seismic or newtonian noise and quantum nature of light. Besides, technological factors impact the reach of advanced detectors in that upgrade strategies are limited by state-of-art performances. In the realm of optics, the quantum limit to sensitivity will be addressed by injecting higher laser power and by exploiting the capabilities of squeezed light. In turn, technological efforts in the preparation of suitable optics able to meet more and more demandig requirements are ongoing. Moreover, solutions to mitigate the effect of known showstoppers such as parametric instablities are being studied. The present day strategy to correct for residual cold defects in the core optics and to counteract the thermal effects due to power absorption is embedded in a set of sensors and actuators integrated in the Advanced Virgo design, the so called Thermal Compensation System (TCS). This system is designed to be focused on the needs of high power operation of the detector, nonetheless it is highly versatile and can deal with foreseen and unexpected issues. We discuss the features of the TCS with emphasis on its versatility and portability to upgraded detectors; we also present the status of the R&D activity in the Tor Vergata labs, highlighting new applications where the methods of TCS can have a relevant impact, such as adaptive mode matching for squeezing and damping of parametric instabilities.

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自适应光学方法在引力波干涉探测器中的应用

当前和未来的引力波探测器的性能受到一些基本因素的限制，如热噪声、地震或牛顿噪声和光的量子性质。此外，技术因素影响了先进探测器的覆盖范围，因为升级策略受到最先进性能的限制。在光学领域，灵敏度的量子限制将通过注入更高的激光功率和利用压缩光的能力来解决。反过来，在准备合适的光学能够满足越来越多的需求的技术努力正在进行中。此外，解决方案，以减轻已知的影响，如参数不稳定性的影响正在研究中。目前的策略，以纠正残余冷缺陷的核心光学和抵消热效应，由于功率吸收是嵌入在一组传感器和执行器集成在先进处女座设计，所谓的热补偿系统(TCS)。该系统主要是针对探测器高功率运行的需要而设计的，但它具有高度的通用性，可以处理可预见和不可预见的问题。我们讨论了TCS的特点，重点是它的多功能性和可移植性，以升级探测器;我们还介绍了Tor Vergata实验室的研发活动现状，重点介绍了TCS方法可以产生相关影响的新应用，例如用于压缩和阻尼参数不稳定性的自适应模式匹配。

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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Proceedings of Gravitational-waves Science&Technology Symposium — PoS(GRASS2018)

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