Characterization of the Virgo seismic environment

Accadia, T; Acernese, F; Astone, P; Ballardin, G; Barone, F; Barsuglia, M; Basti, A; Bauer, Ts; Bebronne, M; Beker, Mg; Belletoile, A; Bitossi, M; Bizouard, Ma; Blom, M; Bondu, F; Bonelli, L; Bonnand, R; Boschi, V; Bosi, L; Bouhou, B; Braccini, S; Bradaschia, C; Branchesi, M; Briant, T; Brillet, A; Brisson, V; Bulik, T; Bulten, Hj; Buskulic, D; Buy, C; Cagnoli, G; Calloni, E; Canuel, B; Carbognani, F; Cavalier, F; Cavalieri, R; Cella, G; Cesarini, E; Chaibi, O; Chassande-Mottin, E; Chincarini, A; Chiummo, A; Cleva, F; Coccia, E; Cohadon, Pf; Colacino, Cn; Colas, J; Colla, A; Colombini, M; Conte, A; Coughlin, M; Coulon, Jp; Cuoco, E; D'Antonio, S; Dattilo, V; Davier, M; Day, R; De Rosa, R; Debreczeni, G; Pozzo, W; del Prete, M; Di Fiore, L; Di Lieto, A; Mdp, Emilio; Di Virgilio, A; Dietz, A; Drago, M; Endroczi, G; Fafone, V; Ferrante, I; Fidecaro, F; Fiori, I; Flaminio, R; Forte, La; Fournier, Jd; Franc, J; Frasca, S; Frasconi, F; Galimberti, M; Gammaitoni, L; Garufi, F; Gaspar, Me; Gemme, G; Genin, E; Gennai, A; Giazotto, A; Gouaty, R; Granata, M; Greverie, C; Guidi, Gm; Hayau, Jf; Heidmann, A; Heitmann, H; Hello, P; Jaranowski, P; Kowalska, I; Krolak, A; Leroy, N; Letendre, N; Tgf, Li; Liguori, N; Lorenzini, M; Loriette, V; Losurdo, G; Majorana, E; Maksimovic, I; Man, N; Mantovani, M; Marchesoni, F; Marion, F; Marque, J; Martelli, F; Masserot, A; Michel, C; Milano, L; Minenkov, Y; Mohan, M; Morgado, N; Morgia, A; Mosca, S; Mours, B; Naticchioni, L; Nocera, F; Pagliaroli, G; Palladino, L; Palomba, C; Paoletti, F; Parisi, M; Pasqualetti, A; Passaquieti, R; Passuello, D; Persichetti, G; Piergiovanni, F; Pietka, M; Pinard, L; Poggiani, R; Prato, M; Prodi, Ga; Punturo, M; Puppo, P; Rabeling, Ds; Racz, I; Rapagnani, P; V, Re; Regimbau, T; Ricci, F; Robinet, F; Rocchi, A; Rolland, L; Romano, R; Rosinska, D; Ruggi, P; Sassolas, B; Sentenac, D; Sperandio, L; Sturani, R; Swinkels, B; Tacca, M; Taffarello, L; Toncelli, A; Tonelli, M; Torre, O; Tournefier, E; Travasso, F; Vajente, G; van den Brand JFJ,; Van Den Broeck, C; van der Putten, S; Vasuth, M; Vavoulidis, M; Vedovato, G; Verkindt, D; Vetrano, F; Vicere, A; Vinet, Jy; Vitale, S; Vocca, H; Ward, Rl; Was, M; Yvert, M; Zadrozny, A; Zendri, Jp

doi:10.1088/0264-9381/29/2/025005

The Virgo gravitational wave detector is an interferometer (ITF) with 3 km arms located in Pisa, Italy. From July to October 2010, Virgo performed its third science run (VSR3) in coincidence with the LIGO detectors. Despite several techniques adopted to isolate the ITF from the environment, seismic noise remains an important issue for Virgo. Vibrations produced by the detector infrastructure (such as air conditioning units, water chillers/heaters, pumps) are found to affect Virgo’s sensitivity, with the main coupling mechanisms being through beam jitter and scattered light processes. The Advanced Virgo design seeks to reduce ITF couplings to environmental noise by having most vibrationsensitive components suspended and in vacuum, as well as muffle and relocate loud machines. During the months of June and July in 2010, a Guralp-3TD ¨ seismometer was stationed at various locations around the Virgo site hosting major infrastructure machines. Seismic data were examined using spectral and coherence analysis with seismic probes close to the detector. The primary aim of this study was to identify noisy machines which seismically affect the ITF environment and thus require mitigation attention. Analyzed machines are located at various distances from the experimental halls, ranging from 10 to 100 m. An attempt is made to measure the attenuation of emitted noise at the ITF and correlate it with the distance from the source and with seismic attenuation models in soil.

Accadia, T., Acernese, F., Astone, P., Ballardin, G., Barone, F., Barsuglia, M., et al. (2012). Characterization of the Virgo seismic environment. CLASSICAL AND QUANTUM GRAVITY, 29(2), 1-10 [10.1088/0264-9381/29/2/025005].

Characterization of the Virgo seismic environment

Accadia T;Acernese F;Astone P;Ballardin G;Barone F;Barsuglia M;Basti A;Bauer TS;Bebronne M;Beker MG;Belletoile A;Bitossi M;Bizouard MA;Blom M;Bondu F;Bonelli L;Bonnand R;Boschi V;Bosi L;Bouhou B;Braccini S;Bradaschia C;Branchesi M;Briant T;Brillet A;Brisson V;Bulik T;Bulten HJ;Buskulic D;Buy C;Cagnoli G;Calloni E;Canuel B;Carbognani F;Cavalier F;Cavalieri R;Cella G;Cesarini E;Chaibi O;Chassande-Mottin E;Chincarini A;Chiummo A;Cleva F;Coccia E;Cohadon PF;Colacino CN;Colas J;Colla A;Colombini M;Conte A;Coughlin M;Coulon JP;Cuoco E;D'Antonio S;Dattilo V;Davier M;Day R;De Rosa R;Debreczeni G;Pozzo W;del Prete M;Di Fiore L;Di Lieto A;Emilio MDP;Di Virgilio A;Dietz A;Drago M;Endroczi G;Fafone V;Ferrante I;Fidecaro F;Fiori I;Flaminio R;Forte LA;Fournier JD;Franc J;Frasca S;Frasconi F;Galimberti M;Gammaitoni L;Garufi F;Gaspar ME;Gemme G;Genin E;Gennai A;Giazotto A;Gouaty R;Granata M;Greverie C;Guidi GM;Hayau JF;Heidmann A;Heitmann H;Hello P;Jaranowski P;Kowalska I;Krolak A;Leroy N;Letendre N;Li TGF;Liguori N;Lorenzini M;Loriette V;Losurdo G;Majorana E;Maksimovic I;Man N;Mantovani M;Marchesoni F;Marion F;Marque J;Martelli F;Masserot A;Michel C;Milano L;Minenkov Y;Mohan M;Morgado N;Morgia A;Mosca S;Mours B;Naticchioni L;Nocera F;Pagliaroli G;Palladino L;Palomba C;Paoletti F;Parisi M;Pasqualetti A;Passaquieti R;Passuello D;Persichetti G;Piergiovanni F;Pietka M;Pinard L;Poggiani R;Prato M;Prodi GA;Punturo M;Puppo P;Rabeling DS;Racz I;Rapagnani P;Re V;Regimbau T;Ricci F;Robinet F;Rocchi A;Rolland L;Romano R;Rosinska D;Ruggi P;Sassolas B;Sentenac D;Sperandio L;Sturani R;Swinkels B;Tacca M;Taffarello L;Toncelli A;Tonelli M;Torre O;Tournefier E;Travasso F;Vajente G;van den Brand JFJ;Van Den Broeck C;van der Putten S;Vasuth M;Vavoulidis M;Vedovato G;Verkindt D;Vetrano F;Vicere A;Vinet JY;Vitale S;Vocca H;Ward RL;Was M;Yvert M;Zadrozny A;Zendri JP

2012

Abstract

The Virgo gravitational wave detector is an interferometer (ITF) with 3 km arms located in Pisa, Italy. From July to October 2010, Virgo performed its third science run (VSR3) in coincidence with the LIGO detectors. Despite several techniques adopted to isolate the ITF from the environment, seismic noise remains an important issue for Virgo. Vibrations produced by the detector infrastructure (such as air conditioning units, water chillers/heaters, pumps) are found to affect Virgo’s sensitivity, with the main coupling mechanisms being through beam jitter and scattered light processes. The Advanced Virgo design seeks to reduce ITF couplings to environmental noise by having most vibrationsensitive components suspended and in vacuum, as well as muffle and relocate loud machines. During the months of June and July in 2010, a Guralp-3TD ¨ seismometer was stationed at various locations around the Virgo site hosting major infrastructure machines. Seismic data were examined using spectral and coherence analysis with seismic probes close to the detector. The primary aim of this study was to identify noisy machines which seismically affect the ITF environment and thus require mitigation attention. Analyzed machines are located at various distances from the experimental halls, ranging from 10 to 100 m. An attempt is made to measure the attenuation of emitted noise at the ITF and correlate it with the distance from the source and with seismic attenuation models in soil.

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	Anno
	
				2012
			
	Rivista
	
				CLASSICAL AND QUANTUM GRAVITY
			
	Codice DOI
	
				https://dx.doi.org/10.1088/0264-9381/29/2/025005
			
	Citazione
	
				Accadia, T., Acernese, F., Astone, P., Ballardin, G., Barone, F., Barsuglia, M., et al. (2012). Characterization of the Virgo seismic environment. CLASSICAL AND QUANTUM GRAVITY, 29(2), 1-10 [10.1088/0264-9381/29/2/025005].
			
	Tutti gli autori
	
						Accadia, T; Acernese, F; Astone, P; Ballardin, G; Barone, F; Barsuglia, M; Basti, A; Bauer, Ts; Bebronne, M; Beker, Mg; Belletoile, A; Bitossi, M; Biz...espandi

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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11585/997994

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