Control of the laser frequency of the Virgo gravitational wave interferometer with an in-loop relative frequency stability of 1.0 × 10−21 on a 100 ms time scale

Acernese, F.; Alshourbagy, M.; Antonucci, F.; Aoudia, S.; Arun, K. G.; Astone, P.; Ballardin, G.; Barone, F.; Barsuglia, M.; Bauer, T. S.; Beker, M.; Bigotta, S.; Birindelli, S.; Bizouard, M. A.; Boccara, C.; Bondu, F.; Bonelli, L.; Bosi, L.; Braccini, S.; Bradaschia, C.; Brillet, A.; Brisson, V.; Bulten, H. J.; Buskulic, D.; Cagnoli, G.; Calloni, E.; Campagna, E.; Canuel, B.; Carbognani, F.; Carbone, L.; Cavalier, F.; Cavalieri, R.; Cella, G.; Chassande-Mottin, E.; Chatterji, S.; Chincarini, A.; Cleva, F.; Coccia, E.; Colas, J.; Colla, A.; Colombini, M.; Corda, C.; Corsi, A.; Coulon, J. -P.; Cuoco, E.; D'Antonio, S.; Dari, A.; Dattilo, V.; Davier, M.; Day, R.; De Rosa, R.; Del Prete, M.; Di Fiore, L.; Di Lieto, A.; Di Paolo Emilio, M.; Di Virgilio, A.; Drago, M.; Fafone, V.; Ferrante, I.; Fidecaro, F.; Fiori, I.; Flaminio, R.; Fournier, J. -D.; Franc, J.; Frasca, S.; Frasconi, F.; Freise, A.; Gammaitoni, L.; Garufi, F.; Gemme, G.; Genin, E.; Gennai, A.; Giazotto, A.; Granata, M.; Granata, V.; Greverie, C.; Guidi, G.; Heitmann, H.; Hello, P.; Hild, S.; Huet, D.; La Penna, P.; Leroy, N.; Letendre, N.; Lorenzini, M.; Loriette, V.; Losurdo, G.; Mackowski, J. -M.; Majorana, E.; Man, N.; Mantovani, M.; Marchesoni, F.; Marion, F.; Marque, J.; Martelli, F.; Masserot, A.; Menzinger, F.; Michel, C.; Milano, L.; Minenkov, Y.; Mohan, M.; Moreau, J.; Morgado, N.; Morgia, A.; Mosca, S.; Mours, B.; Neri, I.; Nocera, F.; Pagliaroli, G.; Palomba, C.; Paoletti, F.; Pardi, S.; Pasqualetti, A.; Passaquieti, R.; Passuello, D.; Persichetti, G.; Pichot, M.; Piergiovanni, F.; Pinard, L.; Poggiani, R.; Prato, M.; Prodi, G. A.; Punturo, M.; Puppo, P.; Rabaste, O.; Rapagnani, P.; Re, V.; Regimbau, T.; Ricci, F.; Robinet, F.; Rocchi, A.; Rolland, L.; Romano, R.; Ruggi, P.; Salemi, F.; Sassolas, B.; Sentenac, D.; Sturani, R.; Swinkels, B.; Terenzi, R.; Toncelli, A.; Tonelli, M.; Tournefier, E.; Travasso, F.; Trummer, J.; Vajente, G.; Van Den Brand, J. F. J.; Van Der Putten, S.; Vavoulidis, M.; Vedovato, G.; Verkindt, D.; Vetrano, F.; Vicere, A.; Vinet, J. -Y.; Vocca, H.; Was, M.; Yvert, M.

doi:10.1109/FREQ.2009.5168287

The measurement of the space-time structure variations induced by strong cosmic events (supernovae, coalescing binaries of neutron stars, etc.) requires an oscillator with a relative stability of 10 −21 on time scales typically ≈100 ms. We demonstrate that the Virgo interferometer with a wavelength of 1.064 °m has a laser frequency with an in-loop stability of 1.0 × 10 −21 on a 100 ms time scale, and an in-loop frequency noise of 2 × 10 −7 Hz/√Hz at 10 Hz. We show that this fits the specifications. Two references successively stabilize the laser frequency. The first one is a 144 m long suspended cavity; the second one is the common mode of two perpendicular 3 km long Fabry-Perot cavities. The differential mode of the relative length variations of these two optical cavities is the port where we expect the signal for the gravitational waves; this out-of-loop measurement, less sensitive to laser frequency noise, does not show up correlations with the in-loop error signal. This is the best ever performance of short term laser frequency stabilization reported.

Acernese, F., Alshourbagy, M., Antonucci, F., Aoudia, S., Arun, K.G., Astone, P., et al. (2009). Control of the laser frequency of the Virgo gravitational wave interferometer with an in-loop relative frequency stability of 1.0 × 10−21 on a 100 ms time scale [10.1109/FREQ.2009.5168287].

Control of the laser frequency of the Virgo gravitational wave interferometer with an in-loop relative frequency stability of 1.0 × 10−21 on a 100 ms time scale

F. Acernese;M. Alshourbagy;F. Antonucci;S. Aoudia;K. G. Arun;P. Astone;G. Ballardin;F. Barone;M. Barsuglia;T. S. Bauer;M. Beker;S. Bigotta;S. Birindelli;M. A. Bizouard;C. Boccara;F. Bondu;L. Bonelli;L. Bosi;S. Braccini;C. Bradaschia;A. Brillet;V. Brisson;H. J. Bulten;D. Buskulic;G. Cagnoli;E. Calloni;E. Campagna;B. Canuel;F. Carbognani;L. Carbone;F. Cavalier;R. Cavalieri;G. Cella;E. Chassande-Mottin;S. Chatterji;A. Chincarini;F. Cleva;E. Coccia;J. Colas;A. Colla;M. Colombini;C. Corda;A. Corsi;J. -P. Coulon;E. Cuoco;S. D'Antonio;A. Dari;V. Dattilo;M. Davier;R. Day;R. De Rosa;M. del Prete;L. Di Fiore;A. Di Lieto;M. Di Paolo Emilio;A. Di Virgilio;M. Drago;V. Fafone;I. Ferrante;F. Fidecaro;I. Fiori;R. Flaminio;J. -D. Fournier;J. Franc;S. Frasca;F. Frasconi;A. Freise;L. Gammaitoni;F. Garufi;G. Gemme;E. Genin;A. Gennai;A. Giazotto;M. Granata;V. Granata;C. Greverie;G. Guidi;H. Heitmann;P. Hello;S. Hild;D. Huet;P. La Penna;N. Leroy;N. Letendre;M. Lorenzini;V. Loriette;G. Losurdo;J. -M. Mackowski;E. Majorana;N. Man;M. Mantovani;F. Marchesoni;F. Marion;J. Marque;F. Martelli;A. Masserot;F. Menzinger;C. Michel;L. Milano;Y. Minenkov;M. Mohan;J. Moreau;N. Morgado;A. Morgia;S. Mosca;B. Mours;I. Neri;F. Nocera;G. Pagliaroli;C. Palomba;F. Paoletti;S. Pardi;A. Pasqualetti;R. Passaquieti;D. Passuello;G. Persichetti;M. Pichot;F. Piergiovanni;L. Pinard;R. Poggiani;M. Prato;G. A. Prodi;M. Punturo;P. Puppo;O. Rabaste;P. Rapagnani;V. Re;T. Regimbau;F. Ricci;F. Robinet;A. Rocchi;L. Rolland;R. Romano;P. Ruggi;F. Salemi;B. Sassolas;D. Sentenac;R. Sturani;B. Swinkels;R. Terenzi;A. Toncelli;M. Tonelli;E. Tournefier;F. Travasso;J. Trummer;G. Vajente;J. F. J. van den Brand;S. van der Putten;M. Vavoulidis;G. Vedovato;D. Verkindt;F. Vetrano;A. Vicere;J. -Y. Vinet;H. Vocca;M. Was;M. Yvert

2009

Abstract

The measurement of the space-time structure variations induced by strong cosmic events (supernovae, coalescing binaries of neutron stars, etc.) requires an oscillator with a relative stability of 10 −21 on time scales typically ≈100 ms. We demonstrate that the Virgo interferometer with a wavelength of 1.064 °m has a laser frequency with an in-loop stability of 1.0 × 10 −21 on a 100 ms time scale, and an in-loop frequency noise of 2 × 10 −7 Hz/√Hz at 10 Hz. We show that this fits the specifications. Two references successively stabilize the laser frequency. The first one is a 144 m long suspended cavity; the second one is the common mode of two perpendicular 3 km long Fabry-Perot cavities. The differential mode of the relative length variations of these two optical cavities is the port where we expect the signal for the gravitational waves; this out-of-loop measurement, less sensitive to laser frequency noise, does not show up correlations with the in-loop error signal. This is the best ever performance of short term laser frequency stabilization reported.

Scheda breve

Scheda completa

Scheda completa (DC)

	Anno
	
				2009
			
	Titolo del volume
	
				2009 IEEE International Frequency Control Symposium Joint with the 22nd European Frequency and Time forum
			
	Pagina iniziale
	
				760
			
	Pagina finale
	
				763
			
	Collana/Serie
	
				JOINT CONFERENCE OF THE IEEE INTERNATIONAL FREQUENCY CONTROL AND THE EUROPEAN FREQUENCY AND TIME FORUM
			
	Codice DOI
	
				https://dx.doi.org/10.1109/FREQ.2009.5168287
			
	Citazione
	
				Acernese, F., Alshourbagy, M., Antonucci, F., Aoudia, S., Arun, K.G., Astone, P., et al. (2009). Control of the laser frequency of the Virgo gravitational wave interferometer with an in-loop relative frequency stability of 1.0 × 10−21 on a 100 ms time scale [10.1109/FREQ.2009.5168287].
			
	Tutti gli autori
	
						Acernese, F.; Alshourbagy, M.; Antonucci, F.; Aoudia, S.; Arun, K. G.; Astone, P.; Ballardin, G.; Barone, F.; Barsuglia, M.; Bauer, T. S.; Beker, M.; ...espandi

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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11585/998543

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