Squeezed state degradations due to mode mismatch and thermal aberrations in gravitational wave detectors

TL;DR

This paper analyzes how mode mismatch and thermal aberrations degrade squeezed states in gravitational wave detectors, impacting their sensitivity and future upgrades.

Contribution

It identifies two types of internal mismatch caused by thermal aberrations and describes their different frequency-dependent effects on squeezing degradation.

Findings

Quadratic wavefront mismatch has low-pass frequency dependence.

Higher order thermal aberrations exhibit high-pass behavior.

Different mismatch types affect current and future detector sensitivities.

Abstract

To date, frequency-dependent squeezed light has been used to reduce quantum noise in interferometric gravitational wave detectors by 6.1 dB (a factor of two). Future upgrades and detectors aim to both reduce quantum noise by 10 dB (a factor of three) and to increase the circulating power in the interferometer arm cavities. Achieving these goals will be extremely challenging due, in part, to the degradations to the squeezed state caused by mode mismatch between the internal interferometer optical cavities and between the auxiliary external cavities. It is therefore imperative to gain a detailed understanding of all sources of mismatch and to obtain experience in mitigating their effects in the current detectors in order to improve astrophysical sensitivity now and in the future. Two types of internal mismatch are identified which are due to the thermal aberrations generated when the test mass optics absorb a small fraction of the circulating arm power. It is found that the dynamics responsible for the degradations caused by the mismatch between the quadratic part of the wavefront of two modes has a characteristic low-pass frequency dependence while the dynamics of the mismatch due to all higher order thermal aberrations has a high-pass behavior. As a consequence, the two types of mismatch are predominantly responsible for different squeezing degradations -- some of which are significant for the current detectors and some of which will only be important for future detectors with longer arms. The behavior of these two types of internal mismatch are described and the implications for detector design, operation, and characterization are discussed.