Gravitational wave background

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The gravitational wave background (also GWB and stochastic background) is a possible target of gravitational wave detection experiments. The detection of such a background would have a profound impact on early-universe cosmology and on high-energy physics. The emission of gravitational waves from astrophysical sources can create a stochastic background of gravitational waves. For instance, a sufficiently massive star at the final stage of its evolution will collapse to form either a black hole or a neutron star – in the rapid collapse during the final moments of an explosive supernova event, which can lead to such formations, gravitational waves may theoretically be liberated.^[1][2] Also, in rapidly rotating neutron stars there is a whole class of instabilities driven by the emission of gravitational waves.

Efforts to detect the gravitational wave background are ongoing. On 11 February 2016, the LIGO and Virgo collaborations announced the first direct detection and observation of gravitational waves, which took place in September 2015. In this case, two black holes had collided to produce detectable gravitational waves. This is the first step to discovery of the GWB.^[3][4]

Detection of gravitational waves

LIGO measurement of the gravitational waves at the Hanford (left) and Livingston (right) detectors, compared to the theoretical predicted values.

On 11 February 2016, the LIGO/EGO collaboration announced the detection of gravitational waves, from a signal detected at 10:51 GMT on 14 September 2015^[5] of two black holes with masses of 29 and 36 solar masses merging around 1.3 billion light years away. The mass of the new black hole obtained from merging the two was 62 solar masses. Energy equivalent to 3 solar masses was emitted as gravitational waves.^[6] The signal was seen by both LIGO detectors, in Livingston and Hanford, with a time difference of 7 milliseconds due to the angle between the two detectors and the source. The signal came from the Southern Celestial Hemisphere, in the rough direction of (but much further away than) the Magellanic Clouds.^[4] The confidence level of the discovery was 99.99994%.^[6] The research made by the Rochester Institute of Technology contributed to the discovery.^[7]

Future observations

Future gravitational waves observatories might see primordial gravitational waves, relics of the early universe, up to less than a second after the Big Bang.^[8][9]

See also

• Cosmic microwave background
• Cosmic neutrino background

References

External links

• Gravitational Wave Experiments and Early Universe Cosmology

Gravitational waves
Detectors	Operational AIGO AURIGA Advanced LIGO (LIGO Scientific Collaboration) CLIO GEO600 Mario Schenberg MiniGrail Decommissioned ALLEGRO TAMA 300 Weber bar Under construction KAGRA Advanced Virgo (European Gravitational Observatory) Proposed AIGO Einstein Telescope INDIGO (LIGO-India) TOBA LISA/eLISA DECIGO Big Bang Observer TianQin
Pulsar timing arrays	EPTA IPTA NANOGrav PPTA
Data analysis	Einstein@Home
Observations	Events List of observations GW150914 (first observation) GW151226 Methods Tests of general relativity Gravitational-wave observatory Interferometric gravitational wave detector Pulsar timing array
Theory	Gravitational-wave astronomy Gravitational wave background

Cosmology
Background	Age of the universe Big Bang Chronology of the universe Universe
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Present universe	FLRW metric Friedmann equations Hubble's law Metric expansion of space Redshift
Future universe	Future of an expanding universe Ultimate fate of the universe
Components	Dark energy Dark fluid Dark matter Lambda-CDM model
Structure formation	Galaxy filament Galaxy formation Large quasar group Large-scale structure Reionization Shape of the universe Structure formation
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