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(Top) 1 Event detection 2 Astrophysical origin 3 Implication for binary black hole formation 4 Graviton mass upper limit 5 See also 6 References

GW170104

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GW170104
Signal of GW170104 measured by Hanford and Livingston
Event type	Gravitational wave
Date	c. 2.9 billion years ago (detected 4 January 2017, 10:11:58.6 UTC)
Instrument	LIGO
Distance	c. 2.9 billion ly
Redshift	0.18 ±0.08
Progenitor	2black holes
Total energy output	≈ 2 M_☉ × c²
Other designations	GW170104
Related media on Commons
[edit on Wikidata]

GW170104 was a gravitational wave signal detected by the LIGO observatory on 4 January 2017. On 1 June 2017, the LIGO and Virgo collaborations announced that they had reliably verified the signal, making it the third such signal announced, after GW150914 and GW151226, and fourth overall.^[1]^[2]

Event detection

[edit]

The signal was detected by LIGO at 10:11:58.6 UTC, with the Hanford detector picking it up 3 milliseconds before the Livingston detector. Automated analyses did not initially identify this event as information about the state of the Hanford detector was not being correctly recorded.^[1] The event was found by a researcher at the Max Planck Institute for Gravitational Physics by visual inspection of triggers from the Livingston detector.^[1]^[3]^[4] The gravitational wave frequency at peak GW strain was 160 to 199 Hz.

Astrophysical origin

[edit]

Analysis indicated the signal resulted from the inspiral and merger of a pair of black holes (BBH) with 31.2+8.4
−6.0 and 19.4+5.3
−5.9 times the mass of the Sun, at a distanceof880+450
−390 megaparsecs (2.9+1.5
−1.3 billion light years) from Earth. The resulting black hole had a mass of 48.7+5.7
−4.6 solar masses, two solar masses having been radiated away as gravitational energy. The peak luminosity of GW170104 was 3.1+0.7
−1.3×10⁴⁹ W.^[1]

Implication for binary black hole formation

[edit]

The spin axes of the black holes were likely misaligned with the axis of the binary orbit. The probability that both spin axes were positively aligned with the orbit is less than 5%. This configuration suggests that the binary black hole system was formed dynamically in a dense star cluster such as a globular cluster, i.e., as a result of gravitational interaction between stars and binary stars, in which case randomly aligned spin axes are expected. The competing scenario, that the system was formed out of a binary star system consisting of two normal (main sequence) stars, is not ruled out but is disfavored as black holes formed in such a binary are more likely to have positively aligned spins.^[1]

Graviton mass upper limit

[edit]

The analysis of GW170104 yielded a new upper bound on the massofgravitons, if gravitons are massive at all. The graviton's Compton wavelength is at least 1.6×10¹⁶ m, or about 1.6 light-years, corresponding to a graviton mass of no more than 7.7×10⁻²³ eV/c².^[1] This Compton wavelength is about 9×10⁹ times greater than the gravitational wavelength of the GW170104 event.

References

[edit]

^ ^a ^b ^c ^d ^e ^f B. P. Abbott; et al. (LIGO Scientific Collaboration and Virgo Collaboration) (1 June 2017). "GW170104: Observation of a 50-Solar-Mass Binary Black Hole Coalescence at Redshift 0.2". Physical Review Letters. 118 (22): 221101. arXiv:1706.01812. Bibcode:2017PhRvL.118v1101A. doi:10.1103/PhysRevLett.118.221101. PMID 28621973.

^ Overbye, Dennis (1 June 2017). "Gravitational Waves Felt From Black-Hole Merger 3 Billion Light-Years Away". New York Times. Retrieved 1 June 2017.

^ "Former U.P. resident helps detect colliding black holes in space". Detroit Free Press. 6 June 2017. Retrieved 17 November 2017.

^ "Gravitationswellen-Entdecker". Berliner Zeitung. 5 June 2017. Retrieved 17 November 2017.

Gravitational-wave astronomy

Detectors

Resonant mass
antennas

Active	NAUTILUS (IGEC) AURIGA (IGEC) MiniGRAIL Mario Schenberg
Past	EXPLORER (IGEC) ALLEGRO (IGEC) NIOBE (IGEC) Stanford gravitational wave detector ALTAIR GEOGRAV AGATA Weber bar
Proposed	TOBA
Past proposals	GRAIL (downsized to MiniGRAIL) TIGA SFERA Graviton (downsized to Mario Schenberg)

Ground-based
interferometers

Active	AIGO (ACIGA) CLIO Fermilab holometer GEO600 Advanced LIGO (LIGO Scientific Collaboration) KAGRA Advanced Virgo (European Gravitational Observatory)
Past	TAMA 300 TAMA 20, later known as LISM TENKO-100 Caltech 40m interferometer
Planned	INDIGO (LIGO-India)
Proposed	Cosmic Explorer Einstein Telescope
Past proposals	LIGO-Australia

Space-based
interferometers

Planned

LISA

Proposed

Pulsar timing arrays

Data analysis

Observations

Events

List of observations
First observation (GW150914)
GW151226
GW170104
GW170608
GW170814
GW170817 (first neutron star merger)
GW190412
GW190521 (first-ever possible light from bh-bh merger)
GW190814 (first-ever "mass gap" collision)
GW200105 (first black hole - neutron star merger)

Methods

Direct detection
- Laser interferometers
- Resonant mass detectors
- Proposed: Atom interferometers
Indirect detection

Theory

Effects / properties

Polarization
Spin-flip
Redshift
Travel with speed of light
h strain
Chirp signal (chirp mass)
Carried energy

Types / sources

Stochastic
- Cosmic inflation-quantum fluctuation
- Phase transition
Binary inspiral
Continuous
- Rotating neutron star
Burst
- Supernova or from unknown sources
Hypothesis
- Colliding cosmic string and other unknown sources

v t e 2017 in space
« 2016 2018 »
Space probe launches	ASTERIA (miniature space telescope; August 2017)
Impact events	Bolides in 2017 2017 China bolide
Selected NEOs	Asteroid close approaches 2017 AG13 2017 BS5 2017 BQ6 2016 WF9 2014 JO25 2017 OO1 2017 QP1 3122 Florence 2017 SX17 2012 TC4 2017 TD6 2017 VL2 2017 VW13 2017 XO2 3200 Phaethon
Exoplanets	HATS-36b HD 113996 b KELT-18b Kepler-19d Kepler-80g Kepler-90i K2-66b K2-138b LHS 1140 b Luyten b NGTS-1b OGLE-2016-BLG-1190Lb OGLE-2016-BLG-1195Lb Ross 128 b Tau Ceti g h TRAPPIST-1 e f g h dark albedoofWASP-12b WASP-107b YZ Ceti b c d
Discoveries	GW170104 Ring of Haumea 2moons of Jupiter GW170608 Saraswati Supercluster GW170814 IGR J17329-2731 (X-ray source) GW170817 neutron star merger ʻOumuamua ULAS J1342+0928 RZ Piscium
Comets	C/2016 U1 (NEOWISE) 41P/Tuttle–Giacobini–Kresák 103P/Hartley C/2015 ER₆₁ (PanSTARRS) C/2015 V2 (Johnson) P/2006 VW139 C/2017 O1 (ASASSN) 96P/Machholz
Space exploration	Cassini retirement (impacted into Saturn; Sep 2017) OSIRIS-REx (Earth gravity assist; Sep 2017)
Outer space portal Category:2016 in outer space — Category:2017 in outer space — Category:2018 in outer space

Physics

Retrieved from "https://en.wikipedia.org/w/index.php?title=GW170104&oldid=1235087586" Categories: ●Binary stars ●Gravitational waves ●January 2017 events ●Stellar black holes ●2017 in science ●2017 in outer space Hidden categories: ●Use dmy dates from June 2017 ●Articles using Infobox astronomical event using locally defined parameters ●This page was last edited on 17 July 2024, at 16:30 (UTC). ●Text is available under the Creative Commons Attribution-ShareAlike License 4.0; additional terms may apply. By using this site, you agree to the Terms of Use and Privacy Policy. Wikipedia® is a registered trademark of the Wikimedia Foundation, Inc., a non-profit organization. ●Privacy policy ●About Wikipedia ●Disclaimers ●Contact Wikipedia ●Code of Conduct ●Developers ●Statistics ●Cookie statement ●Mobile view