First all-sky upper limits from LIGO on the strength of periodic gravitational waves using the Hough transform

B. Abbott; R. Abbott; R. Adhikari; A. Ageev; J. Agresti; B. Allen; J. Allen; R. Amin; S. B. Anderson; W. G. Anderson; M. Araya; H. Armandula; M. Ashley; F. Asiri; P. Aufmuth; C. Aulbert; S. Babak; R. Balasubramanian; S. Ballmer; B. C. Barish; C. Barker; D. Barker; M. Barnes; B. Barr; M. A. Barton; K. Bayer; R. Beausoleil; K. Belczynski; R. Bennett; S. J. Berukoff; J. Betzwieser; B. Bhawal; I. A. Bilenko; G. Billingsley; E. Black; K. Blackburn; L. Blackburn; B. Bland; B. Bochner; L. Bogue; R. Bork; S. Bose; P. R. Brady; V. B. Braginsky; J. E. Brau; D. A. Brown; A. Bullington; A. Bunkowski; A. Buonanno; R. Burgess; D. Busby; W. E. Butler; R. L. Byer; L. Cadonati; G. Cagnoli; J. B. Camp; J. Cannizzo; K. Cannon; C. A. Cantley; L. Cardenas; K. Carter; M. M. Casey; J. Castiglione; A. Chandler; J. Chapsky; P. Charlton; S. Chatterji; S. Chelkowski; Y. Chen; V. Chickarmane; D. Chin; N. Christensen; D. Churches; T. Cokelaer; C. Colacino; R. Coldwell; M. Coles; D. Cook; T. Corbitt; D. Coyne; J. D. E. Creighton; T. D. Creighton; D. R. M. Crooks; P. Csatorday; B. J. Cusack; C. Cutler; J. Dalrymple; E. D’Ambrosio; K. Danzmann; G. Davies; E. Daw; D. DeBra; T. Delker; V. Dergachev; S. Desai; R. DeSalvo; S. Dhurandhar; A. Di Credico; M. Díaz; H. Ding; R. W. P. Drever; R. J. Dupuis; J. A. Edlund; P. Ehrens; E. J. Elliffe; T. Etzel; M. Evans; T. Evans; S. Fairhurst; C. Fallnich; D. Farnham; M. M. Fejer; T. Findley; M. Fine; L. S. Finn; K. Y. Franzen; A. Freise; R. Frey; P. Fritschel; V. V. Frolov; M. Fyffe; K. S. Ganezer; J. Garofoli; J. A. Giaime; A. Gillespie; K. Goda; L. Goggin; G. González; S. Goßler; P. Grandclément; A. Grant; C. Gray; A. M. Gretarsson; D. Grimmett; H. Grote; S. Grunewald; M. Guenther; E. Gustafson; R. Gustafson; W. O. Hamilton; M. Hammond; J. Hanson; C. Hardham; J. Harms; G. Harry; A. Hartunian; J. Heefner; Y. Hefetz; G. Heinzel; I. S. Heng; M. Hennessy; N. Hepler; A. Heptonstall; M. Heurs; M. Hewitson; S. Hild; N. Hindman; P. Hoang; J. Hough; M. Hrynevych; W. Hua; M. Ito; Y. Itoh; A. Ivanov; O. Jennrich; B. Johnson; W. W. Johnson; W. R. Johnston; D. I. Jones; G. Jones; L. Jones; D. Jungwirth; V. Kalogera; E. Katsavounidis; K. Kawabe; S. Kawamura; W. Kells; J. Kern; A. Khan; S. Killbourn; C. J. Killow; C. Kim; C. King; P. King; S. Klimenko; S. Koranda; K. Kötter; J. Kovalik; D. Kozak; B. Krishnan; M. Landry; J. Langdale; B. Lantz; R. Lawrence; A. Lazzarini; M. Lei; I. Leonor; K. Libbrecht; A. Libson; P. Lindquist; S. Liu; J. Logan; M. Lormand; M. Lubinski; H. Lück; M. Luna; T. T. Lyons; B. Machenschalk; M. MacInnis; M. Mageswaran; K. Mailand; W. Majid; M. Malec; V. Mandic; F. Mann; A. Marin; S. Márka; E. Maros; J. Mason; K. Mason; O. Matherny; L. Matone; N. Mavalvala; R. McCarthy; D. E. McClelland; M. McHugh; J. W. C. McNabb; A. Melissinos; G. Mendell; R. A. Mercer; S. Meshkov; E. Messaritaki; C. Messenger; E. Mikhailov; S. Mitra; V. P. Mitrofanov; G. Mitselmakher; R. Mittleman; O. Miyakawa; S. Miyoki; S. Mohanty; G. Moreno; K. Mossavi; G. Mueller; S. Mukherjee; P. Murray; E. Myers; J. Myers; S. Nagano; T. Nash; R. Nayak; G. Newton; F. Nocera; J. S. Noel; P. Nutzman; T. Olson; B. O’Reilly; D. J. Ottaway; A. Ottewill; D. Ouimette; H. Overmier; B. J. Owen; Y. Pan; M. A. Papa; V. Parameshwaraiah; A. Parameswaran; C. Parameswariah; M. Pedraza; S. Penn; M. Pitkin; M. Plissi; R. Prix; V. Quetschke; F. Raab; H. Radkins; R. Rahkola; M. Rakhmanov; S. R. Rao; K. Rawlins; S. Ray-Majumder; V. Re; D. Redding; M. W. Regehr; T. Regimbau; S. Reid; K. T. Reilly; K. Reithmaier; D. H. Reitze; S. Richman; R. Riesen; K. Riles; B. Rivera; A. Rizzi; D. I. Robertson; N. A. Robertson; C. Robinson; L. Robison; S. Roddy; A. Rodriguez; J. Rollins; J. D. Romano; J. Romie; H. Rong; D. Rose; E. Rotthoff; S. Rowan; A. Rüdiger; L. Ruet; P. Russell; K. Ryan; I. Salzman; V. Sandberg; G. H. Sanders; V. Sannibale; P. Sarin; B. Sathyaprakash; P. R. Saulson; R. Savage; A. Sazonov; R. Schilling; K. Schlaufman; V. Schmidt; R. Schnabel; R. Schofield; B. F. Schutz; P. Schwinberg; S. M. Scott; S. E. Seader; A. C. Searle; B. Sears; S. Seel; F. Seifert; D. Sellers; A. S. Sengupta; C. A. Shapiro; P. Shawhan; D. H. Shoemaker; Q. Z. Shu; A. Sibley; X. Siemens; L. Sievers; D. Sigg; A. M. Sintes; J. R. Smith; M. Smith; M. R. Smith; P. H. Sneddon; R. Spero; O. Spjeld; G. Stapfer; D. Steussy; K. A. Strain; D. Strom; A. Stuver; T. Summerscales; M. C. Sumner; M. Sung; P. J. Sutton; J. Sylvestre; A. Takamori; D. B. Tanner; H. Tariq; I. Taylor; R. Taylor; R. Taylor; K. A. Thorne; K. S. Thorne; M. Tibbits; S. Tilav; M. Tinto; K. V. Tokmakov; C. Torres; C. Torrie; G. Traylor; W. Tyler; D. Ugolini; C. Ungarelli; M. Vallisneri; M. van Putten; S. Vass; A. Vecchio; J. Veitch; C. Vorvick; S. P. Vyachanin; L. Wallace; H. Walther; H. Ward; R. Ward; B. Ware; K. Watts; D. Webber; A. Weidner; U. Weiland; A. Weinstein; R. Weiss; H. Welling; L. Wen; S. Wen; K. Wette; J. T. Whelan; S. E. Whitcomb; B. F. Whiting; S. Wiley; C. Wilkinson; P. A. Willems; P. R. Williams; R. Williams; B. Willke; A. Wilson; B. J. Winjum; W. Winkler; S. Wise; A. G. Wiseman; G. Woan; D. Woods; R. Wooley; J. Worden; W. Wu; I. Yakushin; H. Yamamoto; S. Yoshida; K. D. Zaleski; M. Zanolin; I. Zawischa; L. Zhang; R. Zhu; N. Zotov; M. Zucker; J. Zweizig

doi:10.1103/physrevd.72.102004

Upper Limits on a Stochastic Background of Gravitational Waves

Physical Review Letters ◽

10.1103/physrevlett.95.221101 ◽

2005 ◽

Vol 95 (22) ◽

Cited By ~ 67

Author(s):

B. Abbott ◽

R. Abbott ◽

R. Adhikari ◽

J. Agresti ◽

P. Ajith ◽

...

Keyword(s):

Gravitational Waves ◽

Stochastic Background ◽

Upper Limits

Download Full-text

Constraints from LIGO O3 Data on Gravitational-wave Emission Due to R-modes in the Glitching Pulsar PSR J0537–6910

The Astrophysical Journal ◽

10.3847/1538-4357/ac0d52 ◽

2021 ◽

Vol 922 (1) ◽

pp. 71

Author(s):

R. Abbott ◽

T. D. Abbott ◽

S. Abraham ◽

F. Acernese ◽

K. Ackley ◽

...

Keyword(s):

Energy Conservation ◽

Gravitational Wave ◽

Gravitational Waves ◽

Theoretical Models ◽

X Ray ◽

Spin Evolution ◽

Upper Limits ◽

Wave Emission ◽

Using Data

Abstract We present a search for continuous gravitational-wave emission due to r-modes in the pulsar PSR J0537–6910 using data from the LIGO–Virgo Collaboration observing run O3. PSR J0537–6910 is a young energetic X-ray pulsar and is the most frequent glitcher known. The inter-glitch braking index of the pulsar suggests that gravitational-wave emission due to r-mode oscillations may play an important role in the spin evolution of this pulsar. Theoretical models confirm this possibility and predict emission at a level that can be probed by ground-based detectors. In order to explore this scenario, we search for r-mode emission in the epochs between glitches by using a contemporaneous timing ephemeris obtained from NICER data. We do not detect any signals in the theoretically expected band of 86–97 Hz, and report upper limits on the amplitude of the gravitational waves. Our results improve on previous amplitude upper limits from r-modes in J0537-6910 by a factor of up to 3 and place stringent constraints on theoretical models for r-mode-driven spin-down in PSR J0537–6910, especially for higher frequencies at which our results reach below the spin-down limit defined by energy conservation.

Download Full-text

Upper limits on the strength of periodic gravitational waves from PSR J1939+2134

Classical and Quantum Gravity ◽

10.1088/0264-9381/21/5/042 ◽

2004 ◽

Vol 21 (5) ◽

pp. S671-S676 ◽

Cited By ~ 4

Author(s):

B Allen ◽

G Woan ◽

(for the LIGO Scientific Collaboration): ◽

B Abbott ◽

R Abbott ◽

...

Keyword(s):

Gravitational Waves ◽

Upper Limits

Download Full-text

The Gravitational Waves That Bathe the Earth: Upper Limits Based on Theorists' Cherished Beliefs

Essays in General Relativity ◽

10.1016/b978-0-12-691380-4.50016-2 ◽

1980 ◽

pp. 139-155

Author(s):

Mark Zimmermann ◽

Kip S. Thorne

Keyword(s):

Gravitational Waves ◽

The Earth ◽

Upper Limits

Download Full-text

Pulsars Probe the Low-Frequency Gravitational Sky: Pulsar Timing Arrays Basics and Recent Results

Publications of the Astronomical Society of Australia ◽

10.1017/pasa.2018.7 ◽

2018 ◽

Vol 35 ◽

Cited By ~ 13

Author(s):

Caterina Tiburzi

Keyword(s):

Gravitational Waves ◽

Galaxy Formation ◽

Low Frequency ◽

Radio Telescopes ◽

Detection Algorithms ◽

Pulsar Timing ◽

Upper Limits ◽

New Generation ◽

Timing Models ◽

Pulsar Timing Array

AbstractPulsar Timing Array experiments exploit the clock-like behaviour of an array of millisecond pulsars, with the goal of detecting low-frequency gravitational waves. Pulsar Timing Array experiments have been in operation over the last decade, led by groups in Europe, Australia, and North America. These experiments use the most sensitive radio telescopes in the world, extremely precise pulsar timing models and sophisticated detection algorithms to increase the sensitivity of Pulsar Timing Arrays. No detection of gravitational waves has been made to date with this technique, but Pulsar Timing Array upper limits already contributed to rule out some models of galaxy formation. Moreover, a new generation of radio telescopes, such as the Five hundred metre Aperture Spherical Telescope and, in particular, the Square Kilometre Array, will offer a significant improvement to the Pulsar Timing Array sensitivity. In this article, we review the basic concepts of Pulsar Timing Array experiments, and discuss the latest results from the established Pulsar Timing Array collaborations.

Download Full-text

Upper Limits on Gravitational Waves from Scorpius X-1 from a Model-based Cross-correlation Search in Advanced LIGO Data

The Astrophysical Journal ◽

10.3847/1538-4357/aa86f0 ◽

2017 ◽

Vol 847 (1) ◽

pp. 47 ◽

Cited By ~ 23

Author(s):

B. P. Abbott ◽

R. Abbott ◽

T. D. Abbott ◽

F. Acernese ◽

K. Ackley ◽

...

Keyword(s):

Gravitational Waves ◽

Cross Correlation ◽

Model Based ◽

Upper Limits ◽

Correlation Search

Download Full-text

New Searches for Continuous Gravitational Waves from Seven Fast Pulsars

The Astrophysical Journal ◽

10.3847/1538-4357/ac2582 ◽

2021 ◽

Vol 923 (1) ◽

pp. 85

Author(s):

A. Ashok ◽

B. Beheshtipour ◽

M. A. Papa ◽

P. C. C. Freire ◽

B. Steltner ◽

...

Keyword(s):

Gravitational Wave ◽

Gravitational Waves ◽

Continuous Wave ◽

Radio Signal ◽

Rotation Frequency ◽

A Value ◽

Neutron Star Crust ◽

Upper Limits ◽

Drift Scan ◽

Small Band

Abstract We conduct searches for continuous gravitational waves from seven pulsars that have not been targeted in continuous wave searches of Advanced LIGO data before. We target emission at exactly twice the rotation frequency of the pulsars and in a small band around such a frequency. The former search assumes that the gravitational-wave quadrupole is changing in a phase-locked manner with the rotation of the pulsar. The latter search over a range of frequencies allows for differential rotation between the component emitting the radio signal and the component emitting the gravitational waves, for example the crust or magnetosphere versus the core. Timing solutions derived from the Arecibo 327 MHz Drift-Scan Pulsar Survey observations are used. No evidence of a signal is found and upper limits are set on the gravitational-wave amplitude. For one of the pulsars we probe gravitational-wave intrinsic amplitudes just a factor of 3.8 higher than the spin-down limit, assuming a canonical moment of inertia of 1038 kg m2. Our tightest ellipticity constraint is 1.5 × 10−8, which is a value well within the range of what a neutron star crust could support.

Download Full-text

Search Methods for Continuous Gravitational-Wave Signals from Unknown Sources in the Advanced-Detector Era

Universe ◽

10.3390/universe7120474 ◽

2021 ◽

Vol 7 (12) ◽

pp. 474

Author(s):

Rodrigo Tenorio ◽

David Keitel ◽

Alicia M. Sintes

Keyword(s):

Gravitational Wave ◽

Gravitational Waves ◽

Main Stage ◽

Free Precession ◽

Search Methods ◽

Current State ◽

Upper Limits ◽

Interferometric Detectors ◽

Processing Steps ◽

Rule Out

Continuous gravitational waves are long-lasting forms of gravitational radiation produced by persistent quadrupolar variations of matter. Standard expected sources for ground-based interferometric detectors are neutron stars presenting non-axisymmetries such as crustal deformations, r-modes or free precession. More exotic sources could include decaying ultralight boson clouds around spinning black holes. A rich suite of data-analysis methods spanning a wide bracket of thresholds between sensitivity and computational efficiency has been developed during the last decades to search for these signals. In this work, we review the current state of searches for continuous gravitational waves using ground-based interferometer data, focusing on searches for unknown sources. These searches typically consist of a main stage followed by several post-processing steps to rule out outliers produced by detector noise. So far, no continuous gravitational wave signal has been confidently detected, although tighter upper limits are placed as detectors and search methods are further developed.

Download Full-text

Progress Report on the Binary Pulsar 1913+16

Australian Journal of Physics ◽

10.1071/ph790035 ◽

1979 ◽

Vol 32 (2) ◽

pp. 35 ◽

Cited By ~ 3

Author(s):

LA Fowler ◽

JM Cordes ◽

JH Taylor

Keyword(s):

Gravitational Waves ◽

Rotational Frequency ◽

Relativity Theory ◽

Current Status ◽

Present Measurement ◽

Orbital Inclination ◽

Binary Pulsar ◽

Upper Limits ◽

Specific Prediction ◽

The Individual

We report on the current status of observations of the binary pulsar PSRI913+16. The average pulse shape, polarization and spectrum have been found to be similar to those of other pulsars. We find no evidence for irregularities in the rotational frequency of the pulsar. With present measurement uncertainties, timing measurements after a few more years will yield estimates of the individual masses of the pulsar and its companion. the orbital inclination and the derivative of the orbital period. Upper limits on the last parameter are already inconsistent with theories that predict dipole gravitational waves; its measurement will test a specific prediction of general relativity theory and will indirectly demonstrate the existence of gravitational waves.

Download Full-text