OJ 287 | |
---|---|
Observation data (Epoch J2000) | |
Constellation | Cancer |
Right ascension | 08h 54m 48.9s[1] |
Declination | +20° 06′ 31″[1] |
Redshift | 0.306000 [1] |
Distance | 3.5 Gly (1.073 Gpc) |
Type | BL Lac[1] |
Apparent magnitude (V) | 14.83[2] |
Other designations | |
EGO 0851+202,[1] 3EG J0853+1941,[1] RGB J0854+201[1] | |
See also: Quasar, List of quasars | |
OJ 287 is a BL Lac object located 3.5 billion light years away that has produced quasi-periodic optical outbursts going back approximately 120 years, as first apparent on photographic plates from 1891. It was first detected at radio wavelengths during the course of the Ohio Sky Survey.
Its central supermassive black hole is among the largest known, with a mass of 18 billion solar masses[3], more than six times the value calculated for the previous largest object.[4]
The optical light curve shows that OJ 287 has a periodic variation of 11–12 years with a narrow double peak at maximum brightness.[5] This kind of variation suggests[6] that an engine is a binary supermassive black hole where a smaller black hole with a mass of only 100 million MSun orbits the larger one with an observed 11-12 year orbital period. The maximum brightness is obtained when the minor component moves through the accretion disk of the supermassive component at perinigricon.
The mass was calculated by a team led by Mauri Valtonen of Tuorla Observatory in Finland, and the group's results were presented to the public at the 211th meeting of the American Astronomical Society (AAS).[7] The timing of these outbursts allows the precession of the companion's elliptical orbit to be measured (39° per orbit), which allows the mass of the central black hole to be calculated using Albert Einstein's principles of General relativity (see Kepler problem in general relativity).[4]
The accuracy of this measurement has been called into question due to the limited number and precision of observed companion orbits, but the calculated value will be further refined using future measurements. The companion's orbit is decaying via the emission of gravitational radiation and it is expected to merge with the central black hole within approximately 10,000 years.[4] The study has been published in the Astrophysical Journal.[8]
In order to reproduce all the known outbursts, a recent study shows that the rotation of the primary black hole has to be 28% of the maximum allowed rotation for a Kerr black hole.[9]