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We report on an all-sky search for periodic gravitational waves in the frequency band 50-800 Hz and with the frequency time derivative in the range of 0 through -6 x 10(-9) Hz/s. Such a signal could be produced by a nearby spinning and slightly nonaxisymmetric isolated neutron star in our Galaxy. After recent improvements in the search program that yielded a 10x increase in computational efficiency, we have searched in two years of data collected during LIGO's fifth science run and have obtained the most sensitive all-sky upper limits on gravitational-wave strain to date. Near 150 Hz our upper limit on worst-case linearly polarized strain amplitude h(0) is 1 x 10(-24), while at the high end of our frequency range we achieve a worst-case upper limit of 3.8 x 10(-24) for all polarizations and sky locations. These results constitute a factor of 2 improvement upon previously published data. A new detection pipeline utilizing a loosely coherent algorithm was able to follow up weaker outliers, increasing the volume of space where signals can be detected by a factor of 10, but has not revealed any gravitational-wave signals. The pipeline has been tested for robustness with respect to deviations from the model of an isolated neutron star, such as caused by a low-mass or long-period binary companion.
All-sky search for periodic gravitational waves in the full S5 LIGO data
J. Abadie;B. P. Abbott;R. Abbott;T. D. Abbott;M. Abernathy;T. Accadia;F. Acernese;C. Adams;R. Adhikari;C. Affeldt;P. Ajith;B. Allen;G. S. Allen;E. A. Ceron;D. Amariutei;R. S. Amin;S. B. Anderson;W. G. Anderson;K. Arai;M. A. Arain;M. C. Araya;S. M. Aston;P. Astone;D. Atkinson;P. Aufmuth;C. Aulbert;B. E. Aylott;S. Babak;P. Baker;G. Ballardin;S. Ballmer;D. Barker;F. Barone;B. Barr;P. Barriga;L. Barsotti;M. Barsuglia;M. A. Barton;I. Bartos;R. Bassiri;M. Bastarrika;A. Basti;J. Batch;J. Bauchrowitz;T. S. Bauer;M. Bebronne;B. Behnke;M. G. Beker;A. S. Bell;A. Belletoile;I. Belopolski;M. Benacquista;J. M. Berliner;A. Bertolini;J. Betzwieser;N. Beveridge;P. T. Beyersdorf;I. A. Bilenko;G. Billingsley;J. Birch;R. Biswas;M. Bitossi;M. A. Bizouard;E. Black;J. K. Blackburn;L. Blackburn;D. Blair;B. Bland;M. Blom;O. Bock;T. P. Bodiya;C. Bogan;R. Bondarescu;F. Bondu;L. Bonelli;R. Bonnand;R. Bork;M. Born;V. Boschi;S. Bose;L. Bosi;B. Bouhou;S. Braccini;C. Bradaschia;P. R. Brady;V. B. Braginsky;M. Branchesi;J. E. Brau;J. Breyer;T. Briant;D. O. Bridges;A. Brillet;M. Brinkmann;V. Brisson;M. Britzger;A. F. Brooks;D. A. Brown;A. Brummit;T. Bulik;H. J. Bulten;A. Buonanno;J. Burguet Castell;O. Burmeister;D. Buskulic;C. Buy;R. L. Byer;L. Cadonati;G. Cagnoli;E. Calloni;J. B. Camp;P. Campsie;J. Cannizzo;K. Cannon;B. Canuel;J. Cao;C. D. Capano;F. Carbognani;S. Caride;S. Caudill;M. Cavaglia;F. Cavalier;R. Cavalieri;G. Cella;C. Cepeda;E. Cesarini;O. Chaibi;T. Chalermsongsak;E. Chalkley;P. Charlton;E. Chassande Mottin;S. Chelkowski;Y. Chen;A. Chincarini;A. Chiummo;H. Cho;N. Christensen;S. S. Y. , C. T. Y.;S. Chung;G. Ciani;F. Clara;D. E. Clark;J. Clark;J. H. Clayton;F. Cleva;E. Coccia;P. F. Cohadon;C. N. Colacino;J. Colas;A. Colla;M. Colombini;A. Conte;R. Conte;D. Cook;T. R. Corbitt;M. Cordier;N. Cornish;A. Corsi;C. A. Costa;M. Coughlin;J. P. Coulon;P. Couvares;D. M. Coward;D. C. Coyne;J. D. E.;T. D. Creighton;A. M. Cruise;A. Cumming;L. Cunningham;E. Cuoco;R. M. Cutler;K. Dahl;S. L. Danilishin;R. Dannenberg;S. D'Antonio;K. Danzmann;V. Dattilo;B. Daudert;H. Daveloza;M. Davier;G. Davies;E. J. Daw;R. Day;T. Dayanga;R. D. Rosa;D. Debra;G. Debreczeni;J. Degallaix;W. D. Pozzo;M. d. Prete;T. Dent;V. Dergachev;R. DeRosa;R. DeSalvo;S. Dhurandhar;L. D. Fiore;J. DiGuglielmo;A. D. Lieto;I. D. Palma;M. D. P.;A. D. Virgilio;M. Diaz;A. Dietz;F. Donovan;K. L. Dooley;S. Dorsher;Drago, Marco;R. W. P.;J. C. Driggers;Z. Du;J. C. Dumas;S. Dwyer;T. Eberle;M. Edgar;M. Edwards;A. Effler;P. Ehrens;G. Endroczi;R. Engel;T. Etzel;K. Evans;M. Evans;T. Evans;M. Factourovich;V. Fafone;S. Fairhurst;Y. Fan;B. F. Farr;W. Farr;D. Fazi;H. Fehrmann;D. Feldbaum;I. Ferrante;F. Fidecaro;L. S. Finn;I. Fiori;R. P. Fisher;R. Flaminio;M. Flanigan;S. Foley;E. Forsi;L. A. Forte;N. Fotopoulos;J. D. Fournier;J. Franc;S. Frasca;F. Frasconi;M. Frede;M. Frei;Z. Frei;A. Freise;R. Frey;T. T. Fricke;D. Friedrich;P. Fritschel;V. V. Frolov;P. J. Fulda;M. Fyffe;M. Galimberti;L. Gammaitoni;M. R. Ganija;J. Garcia;J. A. Garofoli;F. Garufi;M. E. Gaspar;G. Gemme;R. Geng;E. Genin;A. Gennai;L. A. Gergely;S. Ghosh;J. A. Giaime;S. Giampanis;K. D. Giardina;A. Giazotto;C. Gill;E. Goetz;L. M. Goggin;G. Gonzalez;M. L. Gorodetsky;S. Gossler;R. Gouaty;C. Graef;M. Granata;A. Grant;S. Gras;C. Gray;N. Gray;R. J. S.;A. M. Gretarsson;C. Greverie;R. Grosso;H. Grote;S. Grunewald;G. M. Guidi;C. Guido;R. Gupta;E. K. Gustafson;R. Gustafson;T. Ha;B. Hage;J. M. Hallam;D. Hammer;G. Hammond;J. Hanks;C. Hanna;J. Hanson;J. Harms;G. M. Harry;I. W. Harry;E. D. Harstad;M. T. Hartman;K. Haughian;K. Hayama;J. F. Hayau;T. Hayler;J. Heefner;A. Heidmann;M. C. Heintze;H. Heitmann;P. Hello;M. A. Hendry;I. S. Heng;A. W. Heptonstall;V. Herrera;M. Hewitson;S. Hild;D. Hoak;K. A. Hodge;K. Holt;T. Hong;S. Hooper;D. J. Hosken;J. Hough;E. J. Howell;B. Hughey;S. Husa;S. H. Huttner;T. Huynh Dinh;D. R. Ingram;R. Inta;T. Isogai;A. Ivanov;K. Izumi;M. Jacobson;H. Jang;P. Jaranowski;W. W. Johnson;D. I. Jones;G. Jones;R. Jones;L. Ju;P. Kalmus;V. Kalogera;I. Kamaretsos;S. Kandhasamy;G. Kang;J. B. Kanner;E. Katsavounidis;W. Katzman;H. Kaufer;K. Kawabe;S. Kawamura;F. Kawazoe;W. Kells;D. G. Keppel;Z. Keresztes;A. Khalaidovski;F. Y. Khalili;E. A. Khazanov;B. Kim;C. Kim;D. Kim;H. Kim;K. Kim;N. Kim;Y. M. Kim;P. J. King;M. Kinsey;D. L. Kinzel;J. S. Kissel;S. Klimenko;K. Kokeyama;V. Kondrashov;R. Kopparapu;S. Koranda;W. Z. Korth;I. Kowalska;D. Kozak;V. Kringel;S. Krishnamurthy;B. Krishnan;A. Krolak;G. Kuehn;R. Kumar;P. Kwee;P. K. Lam;M. Landry;M. Lang;B. Lantz;N. Lastzka;C. Lawrie;A. Lazzarini;P. Leaci;C. H. Lee;H. M. Lee;N. Leindecker;J. R. Leong;I. Leonor;N. Leroy;N. Letendre;J. Li;T. G. F.;N. Liguori;P. E. Lindquist;N. A. Lockerbie;D. Lodhia;M. Lorenzini;V. Loriette;M. Lormand;G. Losurdo;J. Luan;M. Lubinski;H. Luck;A. P. Lundgren;E. Macdonald;B. Machenschalk;M. MacInnis;D. M. Macleod;M. Mageswaran;K. Mailand;E. Majorana;I. Maksimovic;N. Man;I. Mandel;V. Mandic;M. Mantovani;A. Marandi;F. Marchesoni;F. Marion;S. Marka;Z. Marka;A. Markosyan;E. Maros;J. Marque;F. Martelli;I. W. Martin;R. M. Martin;J. N. Marx;K. Mason;A. Masserot;F. Matichard;L. Matone;R. A. Matzner;N. Mavalvala;G. Mazzolo;R. McCarthy;D. E. McClelland;S. C. McGuire;G. McIntyre;J. McIver;D. J. A.;G. D. Meadors;M. Mehmet;T. Meier;A. Melatos;A. C. Melissinos;G. Mendell;D. Menendez;R. A. Mercer;S. Meshkov;C. Messenger;M. S. Meyer;H. Miao;C. Michel;L. Milano;J. Miller;Y. Minenkov;V. P. Mitrofanov;G. Mitselmakher;R. Mittleman;O. Miyakawa;B. Moe;P. Moesta;M. Mohan;S. D. Mohanty;S. R. P.;D. Moraru;G. Moreno;N. Morgado;A. Morgia;T. Mori;S. Mosca;K. Mossavi;B. Mours;C. M. Mow Lowry;C. L. Mueller;G. Mueller;S. Mukherjee;A. Mullavey;H. Muller Ebhardt;J. Munch;D. Murphy;P. G. Murray;A. Mytidis;T. Nash;L. Naticchioni;R. Nawrodt;V. Necula;J. Nelson;G. Newton;A. Nishizawa;F. Nocera;D. Nolting;L. Nuttall;E. Ochsner;J. O'Dell;E. Oelker;G. H. Ogin;J. J. Oh;S. H. Oh;R. G. Oldenburg;B. O'Reilly;R. O'Shaughnessy;C. Osthelder;C. D. Ott;D. J. Ottaway;R. S. Ottens;H. Overmier;B. J. Owen;A. Page;G. Pagliaroli;L. Palladino;C. Palomba;Y. Pan;C. Pankow;F. Paoletti;M. A. Papa;M. Parisi;A. Pasqualetti;R. Passaquieti;D. Passuello;P. Patel;M. Pedraza;P. Peiris;L. Pekowsky;S. Penn;C. Peralta;Perreca, Antonio;G. Persichetti;M. Phelps;M. Pickenpack;F. Piergiovanni;M. Pietka;L. Pinard;I. M. Pinto;M. Pitkin;H. J. Pletsch;M. V. Plissi;R. Poggiani;J. Pold;F. Postiglione;M. Prato;V. Predoi;L. R. Price;M. Prijatelj;M. Principe;S. Privitera;R. Prix;Prodi, Giovanni Andrea;L. Prokhorov;O. Puncken;M. Punturo;P. Puppo;V. Quetschke;F. J. Raab;D. S. Rabeling;I. Racz;H. Radkins;P. Raffai;M. Rakhmanov;C. R. Ramet;B. Rankins;P. Rapagnani;V. Raymond;V. Re;K. Redwine;C. M. Reed;T. Reed;T. Regimbau;S. Reid;D. H. Reitze;F. Ricci;R. Riesen;K. Riles;N. A. Robertson;F. Robinet;C. Robinson;E. L. Robinson;A. Rocchi;S. Roddy;C. Rodriguez;M. Rodruck;L. Rolland;J. Rollins;J. D. Romano;R. Romano;J. H. Romie;D. Rosinska;C. Rover;S. Rowan;A. Rudiger;P. Ruggi;K. Ryan;H. Ryll;P. Sainathan;M. Sakosky;F. Salemi;A. Samblowski;L. Sammut;L. S. de;V. Sandberg;S. Sankar;V. Sannibale;L. Santamaria;I. Santiago Prieto;G. Santostasi;B. Sassolas;B. S. Sathyaprakash;S. Sato;P. R. Saulson;R. L. Savage;R. Schilling;S. Schlamminger;R. Schnabel;R. M. S.;B. Schulz;B. F. Schutz;P. Schwinberg;J. Scott;S. M. Scott;A. C. Searle;F. Seifert;D. Sellers;A. S. Sengupta;D. Sentenac;A. Sergeev;D. A. Shaddock;M. Shaltev;B. Shapiro;P. Shawhan;D. H. Shoemaker;A. Sibley;X. Siemens;D. Sigg;A. Singer;L. Singer;A. M. Sintes;G. Skelton;B. J. J.;J. Slutsky;J. R. Smith;M. R. Smith;N. D. Smith;R. J. E.;K. Somiya;B. Sorazu;J. Soto;F. C. Speirits;L. Sperandio;M. Stefszky;A. J. Stein;E. Steinert;J. Steinlechner;S. Steinlechner;S. Steplewski;A. Stochino;R. Stone;K. A. Strain;S. Strigin;A. S. Stroeer;R. Sturani;A. L. Stuver;T. Z. Summerscales;M. Sung;S. Susmithan;P. J. Sutton;B. Swinkels;M. Tacca;L. Taffarello;D. Talukder;D. B. Tanner;S. P. Tarabrin;J. R. Taylor;R. Taylor;P. Thomas;K. A. Thorne;K. S. Thorne;E. Thrane;A. Thuring;C. Titsler;K. V. Tokmakov;A. Toncelli;M. Tonelli;O. Torre;C. Torres;C. I. Torrie;E. Tournefier;F. Travasso;G. Traylor;M. Trias;K. Tseng;D. Ugolini;K. Urbanek;H. Vahlbruch;G. Vajente;M. Vallisneri;J. F. J.;C. V. Den;S. v. der;A. A. van;S. Vass;M. Vasuth;R. Vaulin;M. Vavoulidis;A. Vecchio;G. Vedovato;J. Veitch;P. J. Veitch;C. Veltkamp;D. Verkindt;F. Vetrano;A. Vicere;A. E. Villar;J. Y. Vinet;S. Vitale;S. Vitale;H. Vocca;C. Vorvick;S. P. Vyatchanin;A. Wade;S. J. Waldman;L. Wallace;Y. Wan;X. Wang;Z. Wang;A. Wanner;R. L. Ward;M. Was;P. Wei;M. Weinert;A. J. Weinstein;R. Weiss;L. Wen;S. Wen;P. Wessels;M. West;T. Westphal;K. Wette;J. T. Whelan;S. E. Whitcomb;D. White;B. F. Whiting;C. Wilkinson;P. A. Willems;H. R. Williams;L. Williams;B. Willke;L. Winkelmann;W. Winkler;C. C. Wipf;A. G. Wiseman;H. Wittel;G. Woan;R. Wooley;J. Worden;J. Yablon;I. Yakushin;H. Yamamoto;K. Yamamoto;H. Yang;D. Yeaton Massey;S. Yoshida;P. Yu;M. Yvert;A. Zadrozny;M. Zanolin;J. P. Zendri;F. Zhang;L. Zhang;W. Zhang;Z. Zhang;C. Zhao;N. Zotov;M. E. Zucker;Zweizig
2012
Abstract
We report on an all-sky search for periodic gravitational waves in the frequency band 50-800 Hz and with the frequency time derivative in the range of 0 through -6 x 10(-9) Hz/s. Such a signal could be produced by a nearby spinning and slightly nonaxisymmetric isolated neutron star in our Galaxy. After recent improvements in the search program that yielded a 10x increase in computational efficiency, we have searched in two years of data collected during LIGO's fifth science run and have obtained the most sensitive all-sky upper limits on gravitational-wave strain to date. Near 150 Hz our upper limit on worst-case linearly polarized strain amplitude h(0) is 1 x 10(-24), while at the high end of our frequency range we achieve a worst-case upper limit of 3.8 x 10(-24) for all polarizations and sky locations. These results constitute a factor of 2 improvement upon previously published data. A new detection pipeline utilizing a loosely coherent algorithm was able to follow up weaker outliers, increasing the volume of space where signals can be detected by a factor of 10, but has not revealed any gravitational-wave signals. The pipeline has been tested for robustness with respect to deviations from the model of an isolated neutron star, such as caused by a low-mass or long-period binary companion.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11572/90861
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Il report seguente simula gli indicatori relativi alla propria produzione scientifica in relazione alle soglie ASN 2021-2023 del proprio SC/SSD. Si ricorda che il superamento dei valori soglia (almeno 2 su 3) è requisito necessario ma non sufficiente al conseguimento dell'abilitazione. La simulazione si basa sui dati IRIS e sugli indicatori bibliometrici alla data indicata e non tiene conto di eventuali periodi di congedo obbligatorio, che in sede di domanda ASN danno diritto a incrementi percentuali dei valori. La simulazione può differire dall'esito di un’eventuale domanda ASN sia per errori di catalogazione e/o dati mancanti in IRIS, sia per la variabilità dei dati bibliometrici nel tempo. Si consideri che Anvur calcola i valori degli indicatori all'ultima data utile per la presentazione delle domande.
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