The influence of dual-recycling on parametric instabilities at Advanced LIGO

A. C. Green; D. D. Brown; M. Dovale-Alvarez; C. Collins; H. Miao; C. M. Mow-Lowry; A. Freise

doi:10.1088/1361-6382/aa8af8

The influence of dual-recycling on parametric instabilities at Advanced LIGO

A. C. Green, D. D. Brown, M. Dovale-Alvarez, C. Collins, H. Miao, C. M. Mow-Lowry, A. Freise

Research output: Contribution to Journal › Article › Academic › peer-review

Abstract

Laser interferometers with high circulating power and suspended optics, such as the LIGO gravitational wave detectors, experience an optomechanical coupling effect known as a parametric instability: the runaway excitation of a mechanical resonance in a mirror driven by the optical field. This can saturate the interferometer sensing and control systems and limit the observation time of the detector. Current mitigation techniques at the LIGO sites are successfully suppressing all observed parametric instabilities, and focus on the behaviour of the instabilities in the Fabry-Perot arm cavities of the interferometer, where the instabilities are first generated. In this paper we model the full dual-recycled Advanced LIGO design with inherent imperfections. We find that the addition of the power- and signal-recycling cavities shapes the interferometer response to mechanical modes, resulting in up to four times as many peaks. Changes to the accumulated phase or Gouy phase in the signal-recycling cavity have a significant impact on the parametric gain, and therefore which modes require suppression.

Original language	English
Article number	205004
Journal	Classical and Quantum Gravity
Volume	34
Issue number	20
DOIs	https://doi.org/10.1088/1361-6382/aa8af8
Publication status	Published - 26 Sept 2017
Externally published	Yes

Funding

This work was supported by the Science and Technology Facilities Council Consolidated Grant (number ST/N000633/1) and HM is supported by UK Science and Technology Facilities Council Ernest Rutherford Fellowship (Grant number ST/M005844/11).

Funders	Funder number
UK Research and Innovation
Science and Technology Facilities Council	ST/M005844/1, ST/N000633/1, ST/N000072/1
UK Science and Technology Facilities Council Ernest Rutherford	ST/M005844/11

Keywords

gravitational waves
interferometry
LIGO
parametric instability
radiation pressure
signal recycling

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title = "The influence of dual-recycling on parametric instabilities at Advanced LIGO",

abstract = "Laser interferometers with high circulating power and suspended optics, such as the LIGO gravitational wave detectors, experience an optomechanical coupling effect known as a parametric instability: the runaway excitation of a mechanical resonance in a mirror driven by the optical field. This can saturate the interferometer sensing and control systems and limit the observation time of the detector. Current mitigation techniques at the LIGO sites are successfully suppressing all observed parametric instabilities, and focus on the behaviour of the instabilities in the Fabry-Perot arm cavities of the interferometer, where the instabilities are first generated. In this paper we model the full dual-recycled Advanced LIGO design with inherent imperfections. We find that the addition of the power- and signal-recycling cavities shapes the interferometer response to mechanical modes, resulting in up to four times as many peaks. Changes to the accumulated phase or Gouy phase in the signal-recycling cavity have a significant impact on the parametric gain, and therefore which modes require suppression.",

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AU - Green, A. C.

AU - Brown, D. D.

AU - Dovale-Alvarez, M.

AU - Collins, C.

AU - Miao, H.

AU - Mow-Lowry, C. M.

AU - Freise, A.

PY - 2017/9/26

Y1 - 2017/9/26

N2 - Laser interferometers with high circulating power and suspended optics, such as the LIGO gravitational wave detectors, experience an optomechanical coupling effect known as a parametric instability: the runaway excitation of a mechanical resonance in a mirror driven by the optical field. This can saturate the interferometer sensing and control systems and limit the observation time of the detector. Current mitigation techniques at the LIGO sites are successfully suppressing all observed parametric instabilities, and focus on the behaviour of the instabilities in the Fabry-Perot arm cavities of the interferometer, where the instabilities are first generated. In this paper we model the full dual-recycled Advanced LIGO design with inherent imperfections. We find that the addition of the power- and signal-recycling cavities shapes the interferometer response to mechanical modes, resulting in up to four times as many peaks. Changes to the accumulated phase or Gouy phase in the signal-recycling cavity have a significant impact on the parametric gain, and therefore which modes require suppression.

AB - Laser interferometers with high circulating power and suspended optics, such as the LIGO gravitational wave detectors, experience an optomechanical coupling effect known as a parametric instability: the runaway excitation of a mechanical resonance in a mirror driven by the optical field. This can saturate the interferometer sensing and control systems and limit the observation time of the detector. Current mitigation techniques at the LIGO sites are successfully suppressing all observed parametric instabilities, and focus on the behaviour of the instabilities in the Fabry-Perot arm cavities of the interferometer, where the instabilities are first generated. In this paper we model the full dual-recycled Advanced LIGO design with inherent imperfections. We find that the addition of the power- and signal-recycling cavities shapes the interferometer response to mechanical modes, resulting in up to four times as many peaks. Changes to the accumulated phase or Gouy phase in the signal-recycling cavity have a significant impact on the parametric gain, and therefore which modes require suppression.

KW - gravitational waves

KW - interferometry

KW - LIGO

KW - parametric instability

KW - radiation pressure

KW - signal recycling

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The influence of dual-recycling on parametric instabilities at Advanced LIGO

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