A joint search for gravitational wave bursts with AURIGA and LIGO

Baggio, Lucio; Bignotto, M.; Bonaldi, M.; Cerdonio, M.; Rosa, M. De; Falferi, P.; Fattori, S.; Fortini, P.; Giusfredi, G.; Inguscio, M.; Liguori, N.; Longo, Stefano B.; Marín, F.; Mezzena, R.; Mion, A.; Ortolan, A.; Poggi, S.; Prodi, G. A.; Re, V.; Salemi, F.; Soranzo, G.; Taffarello, L.; Vedovato, G.; Vinante, Andrea; Vitale, S.; Zendri, J.-P.; Abbott, B. P.; Abbott, R.; Adhikari, R. X.; Agresti, J.; Ajith, P.; Allen, B.; Amin, R.; Anderson, S. B.; Anderson, W. G.; Arain, M. A.; Araya, M. C.; Armandula, H.; Ashley, M. C. B.; Aston, S. M.; Aufmuth, P.; Aulbert, C.; Babak, S.; Ballmer, S. W.; Bantilan, H.; Barish, B. C.; Barker, C.; Barker, D.; Barr, B.; Barriga, P.; Barton, M. A.; Bayer, K.; Belczyński, Krzysztof; Betzwieser, J.; Beyersdorf, P. T.; Bhawal, B.; Bilenko, I. A.; Billingsley, G.; Biswas, R.; Black, E.; Blackburn, K.; Blackburn, L.; Blair, David; Bland, B.; Bogenstahl, J.; Bogue, L.; Bork, R.; Boschi, V.; Bose, S.; Brady, P. R.; Braginsky, V. B.; Brau, J. E.; Brinkmann, M.; Brooks, A. F.; Brown, D. A.; Bullington, A.; Bunkowski, A.; Buonanno, A.; Burmeister, O.; Busby, D.; Butler, William E.; Byer, R. L.; Cadonati, L.; Cagnoli, G.; Camp, J. B.; Cannizzo, J. K.; Cannon, K. C.; Cantley, C. A.; Cao, Junwei; Cardenas, L.; Carter, K.; Casey, M. M.; Castaldi, G.; Cepeda, C.; Chalkley, E.; Charlton, P.; Chatterji, S.; Chelkowski, S.; Chen, Y.; Chiadini, F.; Chin, D.; Chin, E.; Chow, J. H.; Christensen, N.; Clark, J. A.; Cochrane, P.; Cokelaer, Thomas; Colacino, C. N.; Coldwell, R. L.; Conte, R.; Cook, D.; Corbitt, T. R.; Coward, D. M.; Coyne, D. C.; Creighton, J. D. E.; Creighton, T. D.; Croce, R. P.; Crooks, D. R. M.; Cruise, A. M.; Cumming, A.; Dalrymple, James; D’Ambrosio, E.; Danzmann, K.; Davies, G. S.; DeBra, D.; Degallaix, J.; Degree, M.; Demma, T.; Dergachev, V.; Desai, S.; DeSalvo, R.; Dhurandhar, S.; Díaz, M. C.; Dickson, J.; Credico, A. Di; Diederichs, G.; Dietz, A.; Doomes, E. E.; Drever, R. W. P.; Dumas, J. C.; Dupuis, R. J.; Dwyer, J. G.; Ehrens, P.; Espinoza, Eduardo; Etzel, T.; Evans, M.; Evans, T. M.; Fairhurst, S.; Fan, Y.; Fazi, D.; Fejer, M. M.; Finn, L. S.; Fiumara, V.; Fotopoulos, N.; Franzen, A.; Franzen, K. Y.; Freise, A.; Frey, R.; Fricke, T. T.; Fritschel, P.; Фролов, В. В.; Fyffe, M.; Galdi, Vincenzo; Ganezer, K. S.; Garofoli, J.; Gholami, I.; Giaime, J. A.; Giampanis, S.; Giardina, K. D.; Goda, Keisuke; Goetz, E.; Goggin, L. M.; González, Gabriela; Goßler, S.; Grant, A.; Gras, S.; Gray, C.; Gray, Malcolm B.; Greenhalgh, J.; Gretarsson, A. M.; Grosso, R.; Grote, H.; Grünewald, S.; Guenther, M.; Gustafson, R.; Hage, B.; Hammer, D. A.; Hanna, C.; Hanson, J.; Harms, J.; Harry, G. M.; Harstad, E. D.; Hayler, T.; Heefner, J.; Heng, I. S.; Heptonstall, A. W.; Heurs, M.; Hewitson, M.; Hild, S.; Hirose, E.; Hoak, D.; Hosken, David J.; Hough, J.; Howell, E. J.; Hoyland, D.; Huttner, S. H.; Ingram, D. R.; Innerhofer, E.; Ito, Masahiro; Itoh, Y.; Ivanov, A.; Jackrel, D.; Johnson, B.; Johnson, W. W.; Jones, D. I.; Jones, Gareth; Jones, R.; Li, Ju; Kalmus, P.; Kalogera, V.; Kasprzyk, Dimitri; Katsavounidis, E.; Kawabe, K.; Kawamura, Seiji; Kawazoe, F.; Kells, W.; Keppel, D. G.; Khalili, F. Y.; Kim, C.; King, Peter; Kissel, J. S.; Klimenko, S.; Kokeyama, K.; Kondrashov, V.; Kopparapu, R.; Kozak, D. B.; Krishnan, B.; Kwee, P.; Lam, Ping Koy; Landry, M.; Lantz, B.; Lazzarini, A.; Lee, B.; Lei, M.; Leiner, J.; Leonhardt, V.; Leonor, I.; Libbrecht, K. G.; Lindquist, P.; Lockerbie, N. A.; Longo, M.; Lormand, M.; Łubiński, M.; Lück, H.; Machenschalk, B.; MacInnis, M.; Mageswaran, M.; Mailand, K.; Malec, M.; Mandic, V.; Maranò, Stefano; Márka, S.; Markowitz, J.; Maros, E.; Martin, Ian; Marx, J. N.; Mason, K.; Matone, L.; Matta, Vincenzo; Mavalvala, N.; McCarthy, R.; McClelland, D. E.; McGuire, S. C.; McHugh, M.; McKenzie, Kirk; McNabb, J. W.; McWilliams, S. T.; Meier, T.; Melissinos, A. C.; Mendell, G.; Mercer, R. A.; Meshkov, S.; Messenger, C.; Meyers, D.; Михайлов, Е. 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H.; Route, R.; Rowan, S.; Rüdiger, A.; Ruet, Laurent; Russell, P.; Ryan, K.; Sakata, S.; Samidi, M.; Jordana, L. Sancho De La; Sandberg, V.; Sanders, G. H.; Sannibale, V.; Saraf, S.; Sarin, P.; Sathyaprakash, B. S.; Sato, S.; Saulson, P. R.; Savage, R. L.; Savov, P.; Sazonov, A.; Schediwy, Sascha; Schilling, R.; Schnabel, R.; Schofield, R. M. S.; Schutz, B. F.; Schwinberg, P.; Scott, S. M.; Searle, A. C.; Sears, B.; Seifert, F.; Sellers, D.; Sengupta, A. S.; Shawhan, P.; Shoemaker, D. H.; Sibley, A.; Siemens, X.; Sigg, D.; Sinha, S.; Sintes, A. M.; Slagmolen, B. J. J.; Slutsky, J.; Smith, J. R.; Smith, M. R.; Somiya, K.; Strain, K. A.; Strom, D.; Stuver, A. L.; Summerscales, T. Z.; Sun, K. X.; Sung, M.; Sutton, P. J.; Takahashi, Hideya; Tanner, D. B.; Tarallo, M.; Taylor, Robert W.; Thacker, John G.; Thorne, K. A.; Thorne, Kip S.; Thüring, A.; Tinto, Massimo; Tokmakov, K. V.; Torres, C. V.; Torrie, C. I.; Traylor, G.; Trias, M.; Tyler, W.; Ugolini, D.; Ungarelli, C.; Urbánek, Karel; Vahlbruch, H.; Vallisneri, Michele; Broeck, C. Van Den; Putten, M. van; Varvella, M.; Vass, S.; Vecchio, A.; Veitch, J.; Veitch, P. J.; Villar, A.; Vorvick, C.; Vyachanin, S. P.; Waldman, S. J.; Wallace, L.; Ward, H.; Ward, R. L.; Watts, K.; Webber, David; Weidner, A.; Weinert, M.; Weinstein, A. J.; Weiss, R.; Wen, S.; Wette, K.; Whelan, J. T.; Whitbeck, D. M.; Whitcomb, S. E.; Whiting, B. F.; Wiley, S.; Wilkinson, C.; Willems, P. A.; Williams, L.; Willke, B.; Wilmut, Ian; Winkler, W.; Wipf, C. C.; Wise, S.; Wiseman, Alan; Woan, G.; Woods, D.; Wooley, R.; Worden, J.; Wu, W.; Yakushin, I.; Yamamoto, H.; Yan, Z.; Yoshida, S.; Yunes, Nicolás; Zanolin, M.; Zhang, J.; Zhang, L.; Zhao, C.; Zotov, N.; Zucker, M. E.; Mühlen, Heribert; Zweizig, J.

doi:10.1088/0264-9381/25/9/095004

Cited by 17 publications

(13 citation statements)

References 24 publications

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“…Other all-sky burst searches in the last decade have included joint searches with the TAMA detector [146] (in addition to a joint coalescence search [145]), with the AURIGA detector [224] and with the GEO 600 detector [225]. In addition, there have been special searches for high-frequency bursts [226] (central frequency in the range 1 − 6 kHz in S5 data and for cosmic string cusp bursts [227] (see section 2.4) in S4 data.…”

Section: All-sky Burst Searchesmentioning

confidence: 99%

Gravitational waves: Sources, detectors and searches

Riles

2013

Progress in Particle and Nuclear Physics

120

148

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Gravitational wave science should transform in this decade from a study of what has not been seen to a full-fledged field of astronomy in which detected signals reveal the nature of cataclysmic events and exotic objects. The LIGO Scientific Collaboration and Virgo Collaboration have recently completed joint data runs of unprecedented sensitivities to gravitational waves. So far, no gravitational radiation has been seen (although data mining continues). It seems likely that the first detection will come from 2nd-generation LIGO and Virgo interferometers now being installed. These new detectors are expected to detect ∼40 coalescences of neutron star binary systems per year at full sensitivity. At the same time, research and development continues on 3rd-generation underground interferometers and on space-based interferometers. In parallel there is a vigorous effort in the radio pulsar community to detect ∼several-nHz gravitational waves via the timing residuals from an array of pulsars at different locations in the sky. As the dawn of gravitational wave astronomy nears, this review, intended primarily for interested particle and nuclear physicists, describes what we have learned to date and the prospects for direct discovery of gravitational waves.

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Section: All-sky Burst Searchesmentioning

confidence: 99%

Gravitational waves: Sources, detectors and searches

Riles

2013

Progress in Particle and Nuclear Physics

120

148

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“…Since ν bbn < ν LV < ν max the wide-band interferometers are an ideal instrument to investigate the relic graviton spectrum in the unknown territory where there are neither direct nor indirect tests on the thermal history of the plasma. The problem is that, as it will be carefully shown, the spectral energy density of the relic gravitons produced within the ΛCDM model is quite minute and it is undetectable by interferometers even in their advanced version where the sensitivity is expected to improve by 5 or even 6 orders of magnitude in comparison with the present performances [34,35,36] (see also [37] and [38]). This impasse, as previously stressed, stems from the assumption that, right after inflation, the radiation-dominated evolution kicks in almost suddenly.…”

Section: Wide-band Interferometersmentioning

confidence: 99%

The thermal history of the plasma and high-frequency gravitons

Giovannini

2009

Class. Quantum Grav.

138

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Possible deviations from a radiation-dominated evolution, occurring prior to the synthesis of light nuclei, impacted on the spectral energy density of high-frequency gravitons. For a systematic scrutiny of this situation, the ΛCDM paradigm must be complemented by (at least two) physical parameters describing, respectively, a threshold frequency and a slope. The supplementary frequency scale sets the lower border of a high-frequency domain where the spectral energy grows with a slope which depends, predominantly, upon the total sound speed of the plasma right after inflation. While the infra-red region of the graviton energy spectrum is nearly scale-invariant, the expected signals for typical frequencies larger than 0.01 nHz are hereby analyzed in a modelindependent framework by requiring that the total sound speed of the post-inflationary plasma be smaller than the speed of light. Current (e.g. low-frequency) upper limits on the tensor power spectra (determined from the combined analysis of the three large-scale data sets) are shown to be compatible with a detectable signal in the frequency range of wide-band interferometers. In the present context, the scrutiny of the early evolution of the sound speed of the plasma can then be mapped onto a reliable strategy of parameter extraction including not only the well established cosmological observables but also the forthcoming data from wide band interferometers.1 e-mail address: massimo.giovannini@cern.ch 5 The overdot will denote throughout the paper a derivation with respect to the cosmic time coordinate t while the prime will denote a derivation with respect to the conformal time coordinate τ .6 Forthcoming projects like Clover [27], Brain [28], Quiet [29] and Spider [30] have polarization as specific target.

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“…Since ν bbn < ν LV < ν max , wide-band interferometers represent an ideal instrument to investigate the relic graviton spectrum at high-frequencies. The spectral energy density of the relic gravitons produced within the ΛCDM model is quite minute and it is undetectable by interferometers even in their advanced version where the sensitivity is expected to improve by 5 or even 6 orders of magnitude in comparison with the present performances [63,64,65] (see also [66] and [67]). In Fig.…”

Section: Short Wavelength Gravitons and Wide-band Interferometersmentioning

confidence: 99%

Stochastic backgrounds of relic gravitons: a theoretical appraisal

Giovannini

2010

PMC Phys A

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Stochastic backgrounds or relic gravitons, if ever detected, will constitute a prima facie evidence of physical processes taking place during the earliest stages of the evolution of the plasma. The essentials of the stochastic backgrounds of relic gravitons are hereby introduced and reviewed. The pivotal observables customarily employed to infer the properties of the relic gravitons are discussed both in the framework of the ΛCDM paradigm as well as in neighboring contexts. The complementarity between experiments measuring the polarization of the Cosmic Microwave Background (such as, for instance, WMAP, Capmap, Quad, Cbi, just to mention a few) and wide band interferometers (e.g. Virgo, Ligo, Geo, Tama) is emphasized. While the analysis of the microwave sky strongly constrains the low-frequency tail of the relic graviton spectrum, wide-band detectors are sensitive to much higher frequencies where the spectral energy density depends chiefly upon the (poorly known) rate of post-inflationary expansion.

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A joint search for gravitational wave bursts with AURIGA and LIGO

Cited by 17 publications

References 24 publications

Gravitational waves: Sources, detectors and searches

Gravitational waves: Sources, detectors and searches

The thermal history of the plasma and high-frequency gravitons

Stochastic backgrounds of relic gravitons: a theoretical appraisal

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