GWTC-1: A Gravitational-Wave Transient Catalog of Compact Binary Mergers Observed by LIGO and Virgo during the First and Second Observing Runs

Abbott, B. P.; Abbott, R.; Abbott, T. D.; Abraham, S.; Acernese, F.; Ackley, K.; Adams, C.; Adhikari, R. X.; Adya, V. B.; Affeldt, C.; Agathos, M.; Agatsuma, K.; Aggarwal, N.; Aguiar, O. D.; Aiello, L.; Ain, A.; Ajith, P.; Allen, G.; Allocca, A.; Aloy, M. Á.; Altin, P. A.; Amato, A.; Ananyeva, A.; Anderson, S. B.; Anderson, W. G.; Angelova, S. V.; Antier, S.; Appert, S.; Arai, K.; Araya, M. C.; Areeda, J. S.; Arène, M.; Arnaud, N.; Arun, K. G.; Ascenzi, S.; Ashton, G.; Aston, S. M.; Astone, P.; Aubin, F.; Aufmuth, P.; AultONeal, K.; Austin, C.; Avendano, V.; Avila-Alvarez, A.; Babak, S.; Bacon, P.; Badaracco, F.; Bader, M. K. M.; Bae, S.; Baker, P. T.; Baldaccini, F.; Ballardin, G.; Ballmer, S. W.; Banagiri, S.; Barayoga, J. C.; Barclay, S. E.; Barish, B. C.; Barker, D.; Barkett, K.; Barnum, S.; Barone, F.; Barr, B.; Barsotti, L.; Barsuglia, M.; Bárta, D.; Bartlett, J.; Bartos, I.; Bassiri, R.; Basti, A.; Bawaj, M.; Bayley, J. C.; Bazzan, M.; Bécsy, B.; Bejger, M.; Belahcene, I.; Bell, A. S.; Beniwal, D.; Berger, B. K.; Bergmann, G.; Bernuzzi, Sebastiano; Bero, J. J.; Berry, C. P. L.; Bersanetti, D.; Bertolini, A.; Betzwieser, J.; Bhandare, R.; Bidler, J.; Bilenko, I. A.; Bilgili, S. A.; Billingsley, G.; Birch, J.; Birney, R.; Birnholtz, O.; Biscans, S.; Biscoveanu, S.; Bisht, A.; Bitossi, M.; Bizouard, M. A.; Blackburn, J. K.; Blackman, J.; Blair, C. D.; Blair, D. G.; Blair, R. M.; Bloemen, S.; Bode, N.; Boër, M.; Boetzel, Y.; Bogaert, G.; Bondu, F.; Bonilla, E.; Bonnand, R.; Booker, P.; Boom, B. A.; Booth, C. D.; Bork, R.; Boschi, V.; Bose, S.; Bossie, K.; Bossilkov, V.; Bosveld, J.; Bouffanais, Y.; Bozzi, A.; Bradaschia, C.; Brady, P. R.; Bramley, A.; Branchesi, M.; Brau, J. E.; Briant, T.; Briggs, J. H.; Brighenti, F.; Brillet, A.; Brinkmann, M.; Brisson, V.; Brockill, P.; Brooks, A. F.; Brown, D. D.; Brunett, S.; Buikema, A.; Bulik, T.; Bulten, H. J.; Buonanno, A.; Buskulic, D.; Rosell, M. J. B.; Buy, C.; Byer, R. L.; Cabero, M.; Cadonati, L.; Cagnoli, G.; Cahillane, C.; Bustillo, J. Calderón; Callister, T. A.; Calloni, E.; Camp, J. B.; Campbell, William A.; Canepa, M.; Cannon, K. C.; Cao, H.; Cao, Junwei; Capocasa, E.; Carbognani, F.; Caride, S.; Carney, M. F.; Carullo, G.; Díaz, J. Casanueva; Casentini, C.; Caudill, S.; Cavaglià, M.; Cavalier, F.; Cavalieri, R.; Cella, G.; Cerdá–Durán, P.; Cerretani, G.; Cesarini, E.; Chaibi, O.; Chakravarti, K.; Chamberlin, S. J.; Chan, M.; Chao, S.; Charlton, P.; Chase, E. A.; Chassande–Mottin, E.; Chatterjee, Debarati; Chaturvedi, M.; Chatziioannou, Katerina; Cheeseboro, B. D.; Chen, H. Y.; Chen, X.; Chen, Y.; Cheng, H.-P.; Cheong, C. K.; Chia, H. Y.; Chincarini, A.; Chiummo, A.; Cho, G.; Cho, H. S.; Cho, M.; Christensen, N.; Chu, Q.; Chua, S.; Chung, K. W.; Chung, S.; Ciani, G.; Ciobanu, A. A.; Ciolfi, R.; Cipriano, F.; Cirone, A.; Clara, F.; Clark, J. A.; Clearwater, P.; Cleva, F.; Cocchieri, C.; Coccia, E.; Cohadon, P.-F.; Cohen, D.; Colgan, R.; Colleoni, M.; Collette, Christophe; Collins, Chris; Cominsky, L.; Constancio, M.; Conti, L.; Cooper, S. J.; Corban, P.; Corbitt, T. R.; Cordero-Carrión, I.; Corley, K. R.; Cornish, N.; Corsi, A.; Cortese, S.; Costa, César Augusto Soares da; Cotesta, R.; Coughlin, M. W.; Coughlin, S. B.; Coulon, J.-P.; Countryman, S. T.; Couvares, P.; Covas, P. B.; Cowan, E. E.; Coward, D. M.; Cowart, M. J.; Coyne, D. C.; Coyne, R.; Creighton, J. D. E.; Creighton, T. D.; Cripe, J.; Croquette, M.; Crowder, S. G.; Cullen, T. J.; Cumming, A.; Cunningham, L.; Cuoco, E.; Canton, T. Dal; Dálya, G.; Danilishin, S. L.; D’Antonio, S.; Danzmann, K.; Dasgupta, Arnab; Costa, C. F. Da Silva; Datrier, L. E. H.; Dattilo, V.; Dave, I.; Davier, M.; Davis, D.; Daw, E. J.; DeBra, D.; Deenadayalan, M.; Degallaix, J.; Laurentis, Mariafelicia De; Deléglise, S.; Pozzo, W. Del; DeMarchi, L. M.; Demos, N.; Dent, T.; Pietri, R. De; Derby, J.; Rosa, R. De; Rossi, C. De; DeSalvo, R.; Varona, O. de; Dhurandhar, S.; Díaz, M. C.; Dietrich, Tim; Fiore, L. Di; Giovanni, M. Di; Girolamo, T. Di; Lieto, A. Di; Ding, B.; Pace, S. Di; Palma, I. Di; Renzo, F. Di; Dmitriev, A.; Doctor, Z.; Donovan, F.; Dooley, K. L.; Doravari, S.; Dorrington, I.; Downes, T. P.; Drago, M.; Driggers, J. C.; Du, Z.; Ducoin, Jean-Grégoire; Dupej, P.; Dwyer, S. E.; Easter, P. J.; Edo, T. B.; Edwards, M. C.; Effler, A.; Ehrens, P.; Eichholz, J.; Eikenberry, S. S.; Eisenmann, M.; Eisenstein, R. A.; Essick, R. C.; Estellés, H.; Estevez, D.; Etienne, Z. B.; Etzel, T.; Evans, M.; Evans, T. M.; Fafone, V.; Fair, H.; Fairhurst, S.; Fan, X.; Farinon, S.; Farr, B.; Farr, W. M.; Fauchon-Jones, E. J.; Favata, M.; Fays, M.; Fazio, M.; Fee, Conan J.; Feicht, J.; Fejer, M. M.; Feng, F.; Fernandez-Galiana, A.; Ferrante, I.; Ferreira, E. C.; Ferreira, T. A.; Ferrini, F.; Fidecaro, F.; Fiori, I.; Fiorucci, D.; Fishbach, M.; Fisher, R. P.; Fishner, J. M.; Fitz-Axen, M.; Flaminio, R.; Fletcher, M.; Flynn, E.; Fong, H.; Font, José A.; Forsyth, P. W. F.; Fournier, J.-D.; Frasca, S.; Frasconi, F.; Frei, Z.; Freise, A.; Frey, R.; Frey, V.; Fritschel, P.; Frolov, V. V.; Fulda, P.; Fyffe, M.; Gabbard, H. A.; Gadre, B. U.; Gaebel, S. M.; Gair, J. R.; Gammaitoni, L.; Ganija, M. R.; Gaonkar, S. G.; García, A.; García-Quirós, C.; Garufi, F.; Gateley, B.; Gaudio, S.; Gaur, G.; Gayathri, V.; Gemme, G.; Genin, É.; Gennai, A.; George, D.; George, J.; Gergely, L.; Germain, V.; Ghonge, S.; Ghosh, Abhirup; Ghosh, Archisman; Ghosh, S.; Giacomazzo, B.; Giaime, J. A.; Giardina, K. D.; Giazotto, A.; Gill, K.; Giordano, G.; Glover, L.; Godwin, P.; Goetz, E.; Goetz, R.; Goncharov, B.; González, Gabriela; Castro, J. M. Gonzalez; Gopakumar, A.; Gorodetsky, M. L.; Gossan, S. E.; Gosselin, M.; Gouaty, R.; Grado, A.; Graef, C.; Granata, M.; Grant, A.; Gras, S.; Grassia, P.; Gray, C.; Gray, R.; Greco, G.; Green, A. C.; Green, R.; Gretarsson, E. 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N.; Isac, J.-M.; Isi, M.; Iyer, B. R.; Izumi, K.; Jacqmin, T.; Jadhav, S. J.; Jani, K.; Janthalur, N. N.; Jaranowski, P.; Jenkins, A. C.; Jiang, Jun; Johnson, D. S.; Johnson-McDaniel, Nathan K.; Jones, Aaron; Jones, David; Jones, R.; Jonker, R. J. G.; Li, Ju; Junker, J.; Kalaghatgi, C. V.; Kalogera, V.; Kamai, B.; Kandhasamy, S.; Kang, G.; Kanner, J. B.; Kapadia, S. J.; Karki, S.; Karvinen, K. S.; Kashyap, R.; Kasprzack, M.; Katsanevas, S.; Katsavounidis, E.; Katzman, W.; Kaufer, S.; Kawabe, K.; Keerthana, N. V.; Kéfélian, F.; Keitel, D.; Kennedy, R.; Key, J. S.; Khalili, F. Y.; Khan, H.; Khan, I.; Khan, S.; Khan, Z.; Хазанов, Е. А.; Khursheed, M.; Kijbunchoo, N.; Kim, Chunglee; Kim, J. C.; Kim, K.; Kim, W.; Kim, W. S.; Kim, Y.-M.; Kimball, C.; King, E. J.; King, Peter; Kinley-Hanlon, M.; Kirchhoff, R.; Kissel, J. S.; Kleybolte, L.; Klika, J. H.; Klimenko, S.; Knowles, T. D.; Koch, P.; Koehlenbeck, S. 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P.; Lynch, R.; Ma, Y.; Macas, R.; Macfoy, S.; MacInnis, M.; Macleod, D. M.; Macquet, A.; Magaña-Sandoval, F.; Zertuche, L. Magaña; Magee, R. M.; Majorana, E.; Maksimovic, I.; Malik, A.; Man, N.; Mandic, V.; Mangano, V.; Mansell, G. L.; Manske, M.; Mantovani, M.; Marchesoni, F.; Marion, F.; Márka, S.; Márka, Z.; Markakis, C.; Markosyan, A. S.; Markowitz, A.; Maros, E.; Marquina, Antonio; Marsat, Sylvain; Martelli, F.; Martin, I. W.; Martin, R. M.; Мартынов, Д. В.; Mason, K.; Massera, E.; Masserot, A.; Massinger, T. J.; Masso-Reid, M.; Mastrogiovanni, S.; Matas, A.; Matichard, F.; Matone, L.; Mavalvala, N.; Mazumder, N.; McCann, J. J.; McCarthy, R.; McClelland, D. E.; McCormick, S.; McCuller, L.; McGuire, S. C.; McIver, J.; McManus, D. J.; McRae, T.; McWilliams, S. T.; Meacher, D.; Meadors, G. D.; Mehmet, M.; Mehta, A. K.; Meidam, J.; Melatos, A.; Mendell, G.; Mercer, R. A.; Mereni, L.; Merilh, E. L.; Merzougui, M.; Meshkov, S.; Messenger, C.; Messick, C.; Metzdorff, R.; Meyers, P. M.; Miao, H.; Michel, C.; Middleton, H.; Михайлов, Е. Е.; Milano, L.; Miller, A. L.; Miller, A.; Millhouse, M.; Mills, J. C.; Milovich-Goff, M. C.; Minazzoli, O.; Minenkov, Y.; Mishkin, A.; Mishra, C.; Mistry, T.; Mitra, S.; Mitrofanov, V. P.; Mitselmakher, G.; Mittleman, R.; Mo, Geoffrey; Moffa, D.; Mogushi, K.; Mohapatra, S. R. P.; Montani, M.; Moore, C. J.; Moraru, D.; Moreno, G.; Morisaki, S.; Mours, B.; Mow–Lowry, C. M.; Mukherjee, Arunava; Mukherjee, D.; Mukherjee, Soma; Mukund, N.; Mullavey, A.; Münch, J.; Muñiz, E. A.; Muratore, M.; Murray, P. G.; Nagar, Alessandro; Nardecchia, I.; Naticchioni, L.; Nayak, R. K.; Neilson, J.; Nelemans, G.; Nelson, T. J. N.; Nery, M.; Neunzert, A.; Ng, K. Y.; Ng, S.; Nguyen, P.; Nichols, David A.; Nielsen, A. B.; Nissanke, S.; Nitz, A.; Nocera, F.; North, C.; Nuttall, L. K.; Obergaulinger, M.; Oberling, J.; O’Brien, B. D.; O’Dea, G. D.; Ogin, G. H.; Oh, J. J.; Oh, Sang Hoon; Ohme, F.; Ohta, Hiroaki; Okada, M. 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doi:10.1103/physrevx.9.031040

Cited by 2,953 publications

(3,259 citation statements)

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“…• For the merger events detected so far by LIGO-Virgo, the effective spin parameter of the binary is compatible to zero, except possibly for few high-mass events [3,4,[20][21][22]. We have shown that a primordial origin of these BH binaries could naturally explain this distribution, especially in the likely scenario in which accretion is quenched at z 10 due to structure formation [41].…”

Section: Resultsmentioning

confidence: 99%

“…where M 1 and M 2 are the individual BH masses, J 1 and J 2 are the corresponding angularmomentum vectors, andL is the direction of the orbital angular momentum. From the observational point of view, there is a general tendency for the effective spin parameter of merger events detected so far to be compatible with zero [3,4], with possible few exceptions [4,[20][21][22] of high-mass events (total mass larger than 50 M ). The available data indicates that the dispersion of χ eff around zero grows with the mass [23].…”

Section: Introductionmentioning

confidence: 99%

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The evolution of primordial black holes and their final observable spins

Luca

Franciolini

Pani

et al. 2020

J. Cosmol. Astropart. Phys.

122

173

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Primordial black holes in the mass range of ground-based gravitational-wave detectors can comprise a significant fraction of the dark matter. Mass and spin measurements from coalescences can be used to distinguish between an astrophysical or a primordial origin of the binary black holes. In standard scenarios the spin of primordial black holes is very small at formation. However, the mass and spin can evolve through the cosmic history due to accretion. We show that the mass and spin of primordial black holes are correlated in a redshift-dependent fashion, in particular primordial black holes with masses below O(30)M are likely non-spinning at any redshift, whereas heavier black holes can be nearly extremal up to redshift z ∼ 10. The dependence of the mass and spin distributions on the redshift can be probed with future detectors such as the Einstein Telescope. The mass and spin evolution affect the gravitational waveform parameters, in particular the distribution of the final mass and spin of the merger remnant, and that of the effective spin of the binary. We argue that, compared to the astrophysical-formation scenario, a primordial origin of black hole binaries might better explain the spin distribution of merger events detected by LIGO-Virgo, in which the effective spin parameter of the binary is compatible to zero except possibly for few high-mass events. Upcoming results from LIGO-Virgo third observation run might reinforce or weaken these predictions.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The evolution of primordial black holes and their final observable spins

Luca

Franciolini

Pani

et al. 2020

J. Cosmol. Astropart. Phys.

122

173

View full text Add to dashboard Cite

show abstract

“…The detection of gravitational waves (GWs) by the LIGO and VIRGO collaborations [1][2][3][4][5][6][7][8][9] from a merging of a pair of heavy black holes seems to be consistent with a prediction of Einstein's general relativity. The GW due to the merging of a neutron star pair has also been observed subsequently [10,11], opening new possibilities for astronomical observation and cosmological research.…”

Section: Introductionmentioning

confidence: 97%

Gravitational waves as a probe of the extra dimension

2019

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We consider the Einstein-Hilbert action without cosmological constant in 5-dimensions and implement the Kaluza-Klein (KK) reduction by compactifying the fifth direction on a circle of small but finite radius. For non-zero compactification radius, the 4dimensional spectrum contains massless and massive KK modes. For the massive KK modes, we retain four KK tensor and one KK scalar modes after a gauge fixing. We treat those massive KK modes as stochastic sources of gravitational wave (GW) with characteristic dependences of the frequencies on the size of the extra dimension. Using the observational bounds on the size of the extra dimension and on the characteristic strain, we make an order estimation on the frequencies and amplitudes of the massive KK modes that can contribute to the GW.

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“…Gravitational-wave astronomy, started in 2015 with the first detection of a black hole merger by LIGO [1], has rapidly become a mature research field. After the groundbreaking observation of the binary neutron star coalescence GW170817 [2]and the publication of the first gravitational-wave sources catalog [3], the network of advanced interferometric detectors (comprised of the two Advanced LIGO [4] and Advanced Virgo [5]) is now performing a third period of data taking (O3), detecting several candidates per month and sending open alerts to the astronomical community [6]. The Japanese detector, KAGRA [7], is about to join the network and is expected to be followed by a fifth detector, LIGO India, in 2024 [8].…”

Section: Introductionmentioning

confidence: 99%

Frequency-Dependent Squeezed Vacuum Source for Broadband Quantum Noise Reduction in Advanced Gravitational-Wave Detectors

et al. 2020

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The astrophysical reach of current and future ground-based gravitational-wave detectors is mostly limited by quantum noise, induced by vacuum fluctuations entering the detector output port. The replacement of this ordinary vacuum field with a squeezed vacuum field has proven to be an effective strategy to mitigate such quantum noise and it is currently used in advanced detectors. However, current squeezing cannot improve the noise across the whole spectrum because of the Heisenberg uncertainty principle: when shot noise at high frequencies is reduced, radiation pressure at low frequencies is increased. A broadband quantum noise reduction is possible by using a more complex squeezing source, obtained by reflecting the squeezed vacuum off a Fabry-Perot cavity, known as filter cavity. Here we report the first demonstration of a frequency-dependent squeezed vacuum source able to reduce quantum noise of advanced gravitational-wave detectors in their whole observation bandwidth. The experiment uses a suspended 300 m long filter cavity, similar to the one planned for KAGRA, Advanced Virgo and Advanced LIGO, and capable of inducing a rotation of the squeezing ellipse below 100 Hz.

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GWTC-1: A Gravitational-Wave Transient Catalog of Compact Binary Mergers Observed by LIGO and Virgo during the First and Second Observing Runs

Cited by 2,953 publications

References 254 publications

The evolution of primordial black holes and their final observable spins

The evolution of primordial black holes and their final observable spins

Gravitational waves as a probe of the extra dimension

Frequency-Dependent Squeezed Vacuum Source for Broadband Quantum Noise Reduction in Advanced Gravitational-Wave Detectors

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