Advanced LIGO detector performance in the fourth observing run

E. Capote; W. Jia; N. Aritomi; M. Nakano; V. Xu; R. Abbott; I.; Abouelfettouh; R. X. Adhikari; A. Ananyeva; S. Appert; S. K. Apple; K. Arai,; S. M. Aston; M. Ball; S. W. Ballmer; D. Barker; L. Barsotti; B. K. Berger; J.; Betzwieser; D. Bhattacharjee; G. Billingsley; S. Biscans; C. D. Blair; N.; Bode; E. Bonilla; V. Bossilkov; A. Branch; A. F. Brooks; D. D. Brown; J.; Bryant; C. Cahillane; H. Cao; F. Clara; J. Collins; C. M. Compton; R.; Cottingham; D. C. Coyne; R. Crouch; J. Csizmazia; A. Cumming; L. P. Dartez,; D. Davis; N. Demos; E. Dohmen; J. C. Driggers; S. E. Dwyer; A. Effler; A.; Ejlli; T. Etzel; M. Evans; J. Feicht; R. Frey; W. Frischhertz; P. Fritschel,; V. V. Frolov; M. Fuentes-Garcia; P. Fulda; M. Fyffe; D. Ganapathy; B.; Gateley; T. Gayer; J. A. Giaime; K. D. Giardina; J. Glanzer; E. Goetz; R.; Goetz; A. W. Goodwin-Jones; S. Gras; C. Gray; D. Griffith; H. Grote; T.; Guidry; J. Gurs; E. D. Hall; J. Hanks; J. Hanson; M. C. Heintze; A. F.; Helmling-Cornell; N. A. Holland; D. Hoyland; H. Y. Huang; Y. Inoue; A. L.; James; A. Jamies; A. Jennings; D. H. Jones; H. B. Kabagoz; S. Karat; S.; Karki; M. Kasprzack; K. Kawabe; N. Kijbunchoo; P. J. King; J. S. Kissel; K.; Komori; A. Kontos; Rahul Kumar; K. Kuns; M. Landry; B. Lantz; M. Laxen; K.; Lee; M. Lesovsky; F. Llamas Villarreal; M. Lormand; H. A. Loughlin; R. Macas,; M. MacInnis; C. N. Makarem; B. Mannix; G. L. Mansell; R. M. Martin; K. Mason,; F. Matichard; N. Mavalvala; N. Maxwell; G. McCarrol; R. McCarthy; D. E.; McClelland; S. McCormick; T. McRae; F. Mera; E. L. Merilh; F. Meylahn; R.; Mittleman; D. Moraru; G. Moreno; A. Mullavey; T. J. N. Nelson; A. Neunzert,; J. Notte; J. Oberling; T. OHanlon; C. Osthelder; D. J. Ottaway; H. Overmier,; W. Parker; O. Patane; A. Pele; H. Pham; M. Pirello; J. Pullin; V. Quetschke,; K. E. Ramirez; K. Ransom; J. Reyes; J. W. Richardson; M. Robinson; J. G.; Rollins; C. L. Romel; J. H. Romie; M. P. Ross; K. Ryan; T. Sadecki; A.; Sanchez; E. J. Sanchez; L. E. Sanchez; R. L. Savage; D. Schaetzl; M. G.; Schiworski; R. Schnabel; R. M. S. Schofield; E. Schwartz; D. Sellers; T.; Shaffer; R. W. Short; D. Sigg; B. J. J. Slagmolen; C. Soike; S. Soni; V.; Srivastava; L. Sun; D. B. Tanner; M. Thomas; P. Thomas; K. A. Thorne; M. R.; Todd; C. I. Torrie; G. Traylor; A. S. Ubhi; G. Vajente; J. Vanosky; A.; Vecchio; P. J. Veitch; A. M. Vibhute; E. R. G. von Reis; J. Warner; B.; Weaver; R. Weiss; C. Whittle; B. Willke; C. C. Wipf; J. L. Wright; H.; Yamamoto; L. Zhang; M. E. Zucker

arXiv:2411.14607·gr-qc·March 5, 2025

Advanced LIGO detector performance in the fourth observing run

E. Capote, W. Jia, N. Aritomi, M. Nakano, V. Xu, R. Abbott, I., Abouelfettouh, R. X. Adhikari, A. Ananyeva, S. Appert, S. K. Apple, K. Arai,, S. M. Aston, M. Ball, S. W. Ballmer, D. Barker, L. Barsotti, B. K. Berger, J., Betzwieser, D. Bhattacharjee, G. Billingsley, S. Biscans

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TL;DR

The paper reports on the fourth LIGO observing run, highlighting unprecedented sensitivity improvements due to upgrades like quantum noise reduction, and details the instrumental enhancements, noise analysis, and commissioning challenges faced.

Contribution

It presents the latest detector performance results and describes new technological upgrades and noise mitigation strategies implemented during the fourth observing run.

Findings

01

Achieved median ranges of 152 Mpc and 160 Mpc for binary neutron star mergers.

02

Implemented significant quantum noise reduction up to 6.1 dB.

03

Enhanced low frequency sensitivity through improved sensors and controls.

Abstract

On May 24th, 2023, the Advanced Laser Interferometer Gravitational-Wave Observatory (LIGO), joined by the Advanced Virgo and KAGRA detectors, began the fourth observing run for a two-year-long dedicated search for gravitational waves. The LIGO Hanford and Livingston detectors have achieved an unprecedented sensitivity to gravitational waves, with an angle-averaged median range to binary neutron star mergers of 152 Mpc and 160 Mpc, and duty cycles of 65.0% and 71.2%, respectively, with a coincident duty cycle of 52.6%. The maximum range achieved by the LIGO Hanford detector is 165 Mpc and the LIGO Livingston detector 177 Mpc, both achieved during the second part of the fourth observing run. For the fourth run, the quantum-limited sensitivity of the detectors was increased significantly due to the higher intracavity power from laser system upgrades and replacement of core optics, and from…

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Taxonomy

TopicsGeophysics and Gravity Measurements · Solar and Space Plasma Dynamics · Astronomical Observations and Instrumentation