GW190814

Gravitational wave of a "mass gap" collision

GW190814
Time–frequency representations (Chatterji et al. 2004) of data containing GW190814, observed by LIGO Hanford (top), LIGO Livingston (middle), and Virgo (bottom). Times are shown relative to 2019 August 14, 21:10:39 UTC. Each detector's data are whitened by their respective noise amplitude spectral density and a Q-transform is calculated. The colorbar displays the normalized energy reported by the Q-transform at each frequency. These plots are not used in our detection procedure and are for visualization purposes only.
Gravitational wave
Date	21:10:39 UTC
Instrument	LIGO, Virgo^[1]^[2]
Right ascension	03h 33m
Declination	04h 45m
Epoch	J2000.0
Distance	241 megaparsecs (790 Mly)^[1]
Other designations	GW190814
Related media on Commons
[edit on Wikidata]

GW 190814 was a gravitational wave (GW) signal observed by the LIGO and Virgo detectors on 14 August 2019 at 21:10:39 UTC,^[2] and having a signal-to-noise ratio of 25 in the three-detector network.^[1] The signal was associated with the astronomical super event S190814bv, located 790 million light years away, in location area 18.5 deg²^{[n 1]}^[1]^[3]^[4] towards Cetus or Sculptor.^[5]^[6]^[7]^[8]^[9]^[10] No optical counterpart was discovered despite an extensive search of the probability region.^[11]

Discovery

In June 2020, astronomers reported details of a compact binary merging, in the "mass gap" of cosmic collisions, of a first-ever 2.50–2.67 M_☉ "mystery object", either an extremely heavy neutron star (that was theorized not to exist) or a too-light black hole, with a 22.2–24.3 M_☉ black hole, that was detected as the gravitational wave GW190814.^[1]^[12]

"We don't know if this object is the heaviest known neutron star or the lightest known black hole, but either way it breaks a record."
— Vicky Kalogera, professor at Northwestern University.^[13]

The mass of the lighter component is estimated to be 2.6 times the mass of the Sun (M_☉ ≈ 1.9891×10³⁰ kg), placing it in the aforementioned mass gap between neutron stars and black holes.^[1]^[13]^[14]^[15]^[16]^[17]

Despite an intensive search, no optical counterpart to the gravitational wave was observed. The lack of emitted light could be consistent with either a situation in which a black hole entirely consumed a neutron star or the merger of two black holes.^[14]

Notes

^ The relatively large and distant area of the sky within which it is claimed to be possible to localize the source.

References

^ ^a ^b ^c ^d ^e ^f Abbott, R.; et al. (23 June 2020). "GW190814: Gravitational Waves from the Coalescence of a 23 Solar Mass Black Hole with a 2.6 Solar Mass Compact Object". The Astrophysical Journal Letters. 896 (2): L44. arXiv:2006.12611. Bibcode:2020ApJ...896L..44A. doi:10.3847/2041-8213/ab960f.
^ ^a ^b Staff (2020). "GW190814 Factsheet - Lowest mass ratio to date - Strongest evidence of higher order modes" (PDF). LIGO. Retrieved 26 June 2020.
^ Greco, G.; et al. (2020). "Handling gravitational-wave sky maps for EM-followUP observations - Second ASTERICS Virtual Observatory School" (PDF). Asterics2020.eu. Retrieved 27 June 2020.
^ Berry, Christopher (10 August 2018). "Sky-localization of Gravitational wave observations". CplBerry.com. Retrieved 27 June 2020.
^ Staff (14 June 2019). "GraceDB - Gravitational-Wave Candidate Event Database - Superevent Info". LIGO. Retrieved 27 June 2020.
^ Staff (23 June 2020). "Black hole or neutron star? - LIGO-Virgo scientists find mystery object in 'mass gap'". Pennsylvania State University. Retrieved 24 June 2020.
^ Starr, Michelle (16 August 2019). "Early Reports Indicate We May Have Detected a Black Hole And Neutron Star Collision". ScienceAlert.com. Retrieved 16 August 2019.
^ Mandelbum, Ryan F. (26 August 2019). "Mystery Deepens Around Newly Detected Ripples in Space-Time". Gizmodo. Retrieved 26 August 2019.
^ Starr, Michelle (11 February 2020). "First Papers on The Black Hole-Neutron Star Merger Are In. Here's What We Didn't See". ScienceAlert.com. Retrieved 11 February 2020.
^ Ackley, K.; et al. (5 February 2020). "Observational constraints on the optical and near-infrared emission from the neutron star-black hole binary merger S190814bv". arXiv:2002.01950v1 [astro-ph.SR].
^ Staff (25 June 2020). "GW190814 Sheds Light on Mass Gap between Neutron Stars and Black Holes". Sci-News.com. Retrieved 26 June 2020.
^ Staff (23 June 2020). "GW190814". LIGO Scientific Collaboration. Retrieved 24 June 2020.
^ ^a ^b Staff (24 June 2020). "Black hole or neutron star? - LIGO-Virgo scientists find mystery object in 'mass gap'". Pennsylvania State University. Retrieved 24 June 2020.
^ ^a ^b University of Birmingham (23 June 2020). "Gravitational wave scientists grapple with the cosmic mystery of GW190814". EurekAlert!. Retrieved 24 June 2020.
^ Overbye, Dennis (24 June 2020). "A Black Hole's Lunch Provides a Treat for Astronomers - Scientists have discovered the heaviest known neutron star, or maybe the lightest known black hole: "Either way it breaks a record."". The New York Times. Retrieved 24 June 2020.
^ Starr, Michelle (24 June 2020). "Astronomers Detect First-Ever Mystery Object in The 'Mass Gap' of Cosmic Collisions". ScienceAlert.com. Retrieved 24 June 2020.
^ Cho, Adrian (24 June 2020). "Gravitational waves reveal lightest black hole ever observed". Science. Retrieved 25 June 2020.

External links

"Detections". LIGO.
Video (2:25): GW190814 binary black hole merger – overview on YouTube (24 June 2020; Science Fellow)
Video (1:32): GW190814 binary black hole merger (animation) on Vimeo (24 June 2020; LIGO Scientific Collaboration)
Video (1:32): GW190814 binary black hole merger (animation) on YouTube (23 June 2020; Max Planck Institute for Gravitational Physics)
Video (0:10): GW190814 gravitational wave from mysterious object on YouTube (23 June 2020; Gravitational-wave Open Science Center (GWOSC))

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	Big Bang Observer DECIGO TianQin

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 B-modes of CMB Pulsar timing array Binary pulsar

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

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