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Continuous wave gravitational radiation from isolated rotating neutron stars is discussed. The general waveform and orders of magnitude for the amplitude are presented for various known pulsars. The specific case of gravitational radiation…

Astrophysics · Physics 2007-05-23 E. Gourgoulhon , S. Bonazzola

We explore here a possible consequence of crustquake, namely, the generation of bursts of gravitational waves (GWs) due to a sudden change in the quadrupole moment (QM) of a deformed pulsar as a result of crustquake. The occurrence of…

High Energy Astrophysical Phenomena · Physics 2020-06-17 Biswanath Layek , Pradeepkumar Yadav

Neutron stars are excellent emitters of gravitational waves. Squeezing matter beyond nuclear densities invites exotic physical processes, many of which violently transfer large amounts of mass at relativistic velocities, disrupting…

High Energy Astrophysical Phenomena · Physics 2015-11-20 Paul D. Lasky

We use the basic equations that predict the emission of gravitational waves according to the Einstein gravitation theory to calculate the luminosities and the amplitudes of the waves generated by binary stars, pulsations of neutron stars,…

General Relativity and Quantum Cosmology · Physics 2010-03-11 M. Cattani

Although gravitational waves only interact weakly with matter, their propagation is affected by a gravitational potential. If a gravitational wave source is eclipsed by a star, measuring these perturbations provides a way to directly…

Solar and Stellar Astrophysics · Physics 2020-02-05 Pablo Marchant , Katelyn Breivik , Christopher P. L. Berry , Ilya Mandel , Shane L. Larson

Rotating neutron stars (NSs) are promising sources of gravitational waves (GWs) in the frequency band of ground-based detectors. They are expected to emit quasi-monochromatic, long-duration GW signals, called continuous waves (CWs), due to…

General Relativity and Quantum Cosmology · Physics 2022-04-20 Federico De Lillo , Jishnu Suresh , Andrew L. Miller

The nonaxisymmetric Ekman flow excited inside a neutron star following a rotational glitch is calculated analytically including stratification and compressibility. For the largest glitches, the gravitational wave strain produced by the…

General Relativity and Quantum Cosmology · Physics 2010-04-15 C. A. van Eysden , A. Melatos

The pulsar magnetosphere is a potential source of continuous gravitational waves due to the rapid charge-discharge process in short timescale, varying the electric-field energy density. We estimate the strain of the continuous gravitational…

General Relativity and Quantum Cosmology · Physics 2026-04-01 Akira Dohi , Asuka Ito , Shota Kisaka

A spinning neutron star (NS) that is asymmetric with respect to its spin axis can emit continuous gravitational wave (GW) signals. The spin frequencies and their distribution of radio millisecond pulsars (MSPs) and accreting MSPs provide…

High Energy Astrophysical Phenomena · Physics 2021-01-25 Wen-Cong Chen

Recent theoretical work has made it plausible for neutron stars (NSs) to lose angular momentum via gravitational radiation on long timescales (around Myrs) while actively accreting. The gravitational waves (GWs) can either be emitted via…

Astrophysics · Physics 2007-05-23 Lars Bildsten

We discuss an astrometric timing effect on data analysis of continuous gravitational waves from rapidly rotating isolated neutron stars. Special attention is directed to the possibility of determining their distances by measuring the…

Astrophysics · Physics 2009-11-11 Naoki Seto

We consider in this work continuous gravitational wave (GW) emission from non-axisymmetric radio pulsars. We treat in some detail the observational issues related to the known radio pulsar sample with the aim of unveiling the actual number…

Astrophysics · Physics 2009-10-30 J. A. de Freitas Pacheco , J. E. Horvath

We present direct upper limits on gravitational wave emission from the Crab pulsar using data from the first nine months of the fifth science run of the Laser Interferometer Gravitational-wave Observatory (LIGO). These limits are based on…

Astrophysics · Physics 2017-01-23 The LIGO Scientific Collaboration , B. Abbott , R. Abbott , R. Adhikari , P. Ajith , B. Allen , G. Allen , R. Amin , S. B. Anderson , W. G. Anderson , M. A. Arain , M. Araya , H. Armandula , P. Armor , Y. Aso , S. Aston , P. Aufmuth , C. Aulbert , S. Babak , S. Ballmer , H. Bantilan , B. C. Barish , C. Barker , D. Barker , B. Barr , P. Barriga , M. A. Barton , M. Bastarrika , K. Bayer , J. Betzwieser , P. T. Beyersdorf , I. A. Bilenko , G. Billingsley , R. Biswas , E. Black , K. Blackburn , L. Blackburn , D. Blair , B. Bland , T. P. Bodiya , L. Bogue , R. Bork , V. Boschi , S. Bose , P. R. Brady , V. B. Braginsky , J. E. Brau , M. Brinkmann , A. Brooks , D. A. Brown , G. Brunet , A. Bullington , A. Buonanno , O. Burmeister , R. L. Byer , L. Cadonati , G. Cagnoli , J. B. Camp , J. Cannizzo , K. Cannon , J. Cao , L. Cardenas , T. Casebolt , G. Castaldi , C. Cepeda , E. Chalkley , P. Charlton , S. Chatterji , S. Chelkowski , Y. Chen , N. Christensen , D. Clark , J. Clark , T. Cokelaer , R. Conte , D. Cook , T. Corbitt , D. Coyne , J. D. E. Creighton , A. Cumming , L. Cunningham , R. M. Cutler , J. Dalrymple , K. Danzmann , G. Davies , D. DeBra , J. Degallaix , M. Degree , V. Dergachev , S. Desai , R. DeSalvo , S. Dhurandhar , M. Díaz , J. Dickson , A. Dietz , F. Donovan , K. L. Dooley , E. E. Doomes , R. W. P. Drever , I. Duke , J. -C. Dumas , R. J. Dupuis , J. G. Dwyer , C. Echols , A. Effler , P. Ehrens , E. Espinoza , T. Etzel , T. Evans , S. Fairhurst , Y. Fan , D. Fazi , H. Fehrmann , M. M. Fejer , L. S. Finn , K. Flasch , N. Fotopoulos , A. Freise , R. Frey , T. Fricke , P. Fritschel , V. V. Frolov , M. Fyffe , J. Garofoli , I. Gholami , J. A. Giaime , S. Giampanis , K. D. Giardina , K. Goda , E. Goetz , L. Goggin , G. González , S. Gossler , R. Gouaty , A. Grant , S. Gras , C. Gray , M. Gray , R. J. S. Greenhalgh , A. M. Gretarsson , F. Grimaldi , R. Grosso , H. Grote , S. Grunewald , M. Guenther , E. K. Gustafson , R. Gustafson , B. Hage , J. M. Hallam , D. Hammer , C. Hanna , J. Hanson , J. Harms , G. Harry , E. Harstad , K. Hayama , T. Hayler , J. Heefner , I. S. Heng , M. Hennessy , A. Heptonstall , M. Hewitson , S. Hild , E. Hirose , D. Hoak , D. Hosken , J. Hough , S. H. Huttner , D. Ingram , M. Ito , A. Ivanov , B. Johnson , W. W. Johnson , D. I. Jones , ÂG. Jones , R. Jones , L. Ju , P. Kalmus , V. Kalogera , S. Kamat , J. Kanner , D. Kasprzyk , E. Katsavounidis , K. Kawabe , S. Kawamura , F. Kawazoe , W. Kells , D. G. Keppel , F. Ya. Khalili , R. Khan , E. Khazanov , C. Kim , P. King , J. S. Kissel , S. Klimenko , K. Kokeyama , V. Kondrashov , R. K. Kopparapu , D. Kozak , I. Kozhevatov , B. Krishnan , P. Kwee , P. K. Lam , M. Landry , M. M. Lang , B. Lantz , A. Lazzarini , M. Lei , N. Leindecker , V. Leonhardt , I. Leonor , K. Libbrecht , H. Lin , P. Lindquist , N. A. Lockerbie , D. Lodhia , M. Lormand , P. Lu , M. Lubinski , A. Lucianetti , H. Lück , B. Machenschalk , M. MacInnis , M. Mageswaran , K. Mailand , V. Mandic , S. Márka , Z. Márka , A. Markosyan , J. Markowitz , E. Maros , I. Martin , R. M. Martin , J. N. Marx , K. Mason , F. Matichard , L. Matone , R. Matzner , N. Mavalvala , R. McCarthy , D. E. McClelland , S. C. McGuire , M. McHugh , G. McIntyre , G. McIvor , D. McKechan , K. McKenzie , T. Meier , A. Melissinos , G. Mendell , R. A. Mercer , S. Meshkov , C. J. Messenger , D. Meyers , J. Miller , J. Minelli , S. Mitra , V. P. Mitrofanov , G. Mitselmakher , R. Mittleman , O. Miyakawa , B. Moe , S. Mohanty , G. Moreno , K. Mossavi , C. MowLowry , G. Mueller , S. Mukherjee , H. Mukhopadhyay , H. Müller-Ebhardt , J. Munch , P. Murray , E. Myers , J. Myers , T. Nash , J. Nelson , G. Newton , A. Nishizawa , K. Numata , J. O'Dell , G. Ogin , B. O'Reilly , R. O'Shaughnessy , D. J. Ottaway , R. S. Ottens , H. Overmier , B. J. Owen , Y. Pan , C. Pankow , M. A. Papa , V. Parameshwaraiah , P. Patel , M. Pedraza , S. Penn , A. Perreca , T. Petrie , I. M. Pinto , M. Pitkin , H. J. Pletsch , M. V. Plissi , F. Postiglione , M. Principe , R. Prix , V. Quetschke , F. Raab , D. S. Rabeling , H. Radkins , N. Rainer , M. Rakhmanov , M. Ramsunder , H. Rehbein , S. Reid , D. H. Reitze , R. Riesen , K. Riles , B. Rivera , N. A. Robertson , C. Robinson , E. L. Robinson , S. Roddy , A. Rodriguez , A. M. Rogan , J. Rollins , J. D. Romano , J. Romie , R. Route , S. Rowan , A. Rüdiger , L. Ruet , P. Russell , K. Ryan , S. Sakata , M. Samidi , L. Sancho de la Jordana , V. Sandberg , V. Sannibale , S. Saraf , P. Sarin , B. S. Sathyaprakash , S. Sato , P. R. Saulson , R. Savage , P. Savov , S. W. Schediwy , R. Schilling , R. Schnabel , R. Schofield , B. F. Schutz , P. Schwinberg , S. M. Scott , A. C. Searle , B. Sears , F. Seifert , D. Sellers , A. S. Sengupta , P. Shawhan , D. H. Shoemaker , A. Sibley , X. Siemens , D. Sigg , S. Sinha , A. M. Sintes , B. J. J. Slagmolen , J. Slutsky , J. R. Smith , M. R. Smith , N. D. Smith , K. Somiya , B. Sorazu , L. C. Stein , A. Stochino , R. Stone , K. A. Strain , D. M. Strom , A. Stuver , T. Z. Summerscales , K. -X. Sun , M. Sung , P. J. Sutton , H. Takahashi , D. B. Tanner , R. Taylor , R. Taylor , J. Thacker , K. A. Thorne , K. S. Thorne , A. Thüring , K. V. Tokmakov , C. Torres , C. Torrie , G. Traylor , M. Trias , W. Tyler , D. Ugolini , J. Ulmen , K. Urbanek , H. Vahlbruch , C. Van Den Broeck , M. van der Sluys , S. Vass , R. Vaulin , A. Vecchio , J. Veitch , P. Veitch , A. Villar , C. Vorvick , S. P. Vyachanin , S. J. Waldman , L. Wallace , H. Ward , R. Ward , M. Weinert , A. Weinstein , R. Weiss , S. Wen , K. Wette , J. T. Whelan , S. E. Whitcomb , B. F. Whiting , C. Wilkinson , P. A. Willems , H. R. Williams , L. Williams , B. Willke , I. Wilmut , W. Winkler , C. C. Wipf , A. G. Wiseman , G. Woan , R. Wooley , J. Worden , W. Wu , I. Yakushin , H. Yamamoto , Z. Yan , S. Yoshida , M. Zanolin , J. Zhang , L. Zhang , C. Zhao , N. Zotov , M. Zucker , J. Zweizig , G. Santostasi

With the remarkable advent of gravitational-wave astronomy, we have shed light on previously shrouded events: compact binary coalescences. Neutron stars are promising (and confirmed) sources of gravitational radiation and it proves timely…

High Energy Astrophysical Phenomena · Physics 2021-09-20 Fabian Gittins

Magnetars have already been a potential candidate as gravitational wave sources that could be detected by current and future terrestrial as well as ground based gravitational wave detectors. In this article, we focus on the gravitational…

General Relativity and Quantum Cosmology · Physics 2021-11-22 Sourav Roy Chowdhury , Maxim Khlopov

The gravitational waves emitted by neutron stars carry unique information about their structure and composition. Direct detection of these gravitational waves, however, is a formidable technical challenge. In a recent study we quantified…

Solar and Stellar Astrophysics · Physics 2009-11-13 Anna L. Watts , Badri Krishnan

The background of gravitational waves produced by the ensemble of rotating neutron stars (which includes pulsars, magnetars and gravitars) is investigated. A formula for \Omega(f) (commonly used to quantify the background) is derived,…

General Relativity and Quantum Cosmology · Physics 2012-11-07 Pablo A. Rosado

A precondition for the radio emission of pulsars is the existence of strong, small-scale magnetic field structures (`magnetic spots') in the polar cap region. Their creation can proceed via crustal Hall drift out of two qualitatively and…

High Energy Astrophysical Phenomena · Physics 2016-06-01 Arthur George Suvorov , Alpha Mastrano , Ulrich Geppert

We estimate the gravitational wave amplitude as a function of frequency produced during the creation of pulsars from the gravitational collapse of a massive star. The three main quantities needed are the magnitude of the magnetic field…

High Energy Astrophysical Phenomena · Physics 2019-12-06 Leonard S. Kisslinger , Bijit Singha , Zhou Li-juan

We consider the spin evolution of highly magnetized neutron stars in a hypercritical inflow just after their birth in supernovae. Presence of a strong magnetic field could deform the star and if the symmetry axis of the field is misaligned…

Astrophysics · Physics 2009-11-07 Shin Yoshida