Comparison of different sloshing speedmeters

S. H. Huttner; S. L. Danilishin; S. Hild; K. A. Strains

doi:10.1088/1361-6382/ab7bbb

Comparison of different sloshing speedmeters

S. H. Huttner^*, S. L. Danilishin, S. Hild, K. A. Strains

^*Corresponding author for this work

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

Abstract

By numerical simulation, we compare the performance of four speedmeter interferometer configurations with potential application in future gravitational wave detectors. In the absence of optical loss, all four configurations can be adjusted to yield the same sensitivity in a fair comparison. Once we introduce a degree of practicality in the form of lossy optics and mode mismatch, however, the situation changes: the sloshing Sagnac and the speedmeter of Purdue and Chen have almost identical performance showing smaller degradation from the ideal than the speedmeter of Freise and the speedmeter of Miao. In a further step, we show that there is a similar hierarchy in the degree of improvement obtained through the application of 10 dB squeezing to the lossy speedmeters. In this case, the sensitivity of each speedmeter improves, but it is greatest for the sloshing Sagnac and the speedmeter of Purdue and Chen, in particular in the lower part of the target frequency range.

Original language	English
Article number	085022
Number of pages	17
Journal	Classical and Quantum Gravity
Volume	37
Issue number	8
DOIs	https://doi.org/10.1088/1361-6382/ab7bbb
Publication status	Published - 23 Apr 2020

Keywords

gravitational wave detector
speedmeter
interferometer
2-PHOTON QUANTUM OPTICS
FORMALISM

Access to Document

10.1088/1361-6382/ab7bbbLicence: CC BY

Cite this

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title = "Comparison of different sloshing speedmeters",

abstract = "By numerical simulation, we compare the performance of four speedmeter interferometer configurations with potential application in future gravitational wave detectors. In the absence of optical loss, all four configurations can be adjusted to yield the same sensitivity in a fair comparison. Once we introduce a degree of practicality in the form of lossy optics and mode mismatch, however, the situation changes: the sloshing Sagnac and the speedmeter of Purdue and Chen have almost identical performance showing smaller degradation from the ideal than the speedmeter of Freise and the speedmeter of Miao. In a further step, we show that there is a similar hierarchy in the degree of improvement obtained through the application of 10 dB squeezing to the lossy speedmeters. In this case, the sensitivity of each speedmeter improves, but it is greatest for the sloshing Sagnac and the speedmeter of Purdue and Chen, in particular in the lower part of the target frequency range.",

keywords = "gravitational wave detector, speedmeter, interferometer, 2-PHOTON QUANTUM OPTICS, FORMALISM",

author = "Huttner, {S. H.} and Danilishin, {S. L.} and S. Hild and Strains, {K. A.}",

note = "Publisher Copyright: {\textcopyright} 2020 The Author(s). Published by IOP Publishing Ltd.",

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T1 - Comparison of different sloshing speedmeters

AU - Huttner, S. H.

AU - Danilishin, S. L.

AU - Hild, S.

AU - Strains, K. A.

PY - 2020/4/23

Y1 - 2020/4/23

N2 - By numerical simulation, we compare the performance of four speedmeter interferometer configurations with potential application in future gravitational wave detectors. In the absence of optical loss, all four configurations can be adjusted to yield the same sensitivity in a fair comparison. Once we introduce a degree of practicality in the form of lossy optics and mode mismatch, however, the situation changes: the sloshing Sagnac and the speedmeter of Purdue and Chen have almost identical performance showing smaller degradation from the ideal than the speedmeter of Freise and the speedmeter of Miao. In a further step, we show that there is a similar hierarchy in the degree of improvement obtained through the application of 10 dB squeezing to the lossy speedmeters. In this case, the sensitivity of each speedmeter improves, but it is greatest for the sloshing Sagnac and the speedmeter of Purdue and Chen, in particular in the lower part of the target frequency range.

AB - By numerical simulation, we compare the performance of four speedmeter interferometer configurations with potential application in future gravitational wave detectors. In the absence of optical loss, all four configurations can be adjusted to yield the same sensitivity in a fair comparison. Once we introduce a degree of practicality in the form of lossy optics and mode mismatch, however, the situation changes: the sloshing Sagnac and the speedmeter of Purdue and Chen have almost identical performance showing smaller degradation from the ideal than the speedmeter of Freise and the speedmeter of Miao. In a further step, we show that there is a similar hierarchy in the degree of improvement obtained through the application of 10 dB squeezing to the lossy speedmeters. In this case, the sensitivity of each speedmeter improves, but it is greatest for the sloshing Sagnac and the speedmeter of Purdue and Chen, in particular in the lower part of the target frequency range.

KW - gravitational wave detector

KW - speedmeter

KW - interferometer

KW - 2-PHOTON QUANTUM OPTICS

KW - FORMALISM

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