supermassive black hole

black hole in M87Black hole at the center of the massive galaxy M87, about 55 million light-years from Earth, as imaged by the Event Horizon Telescope (EHT). The black hole is 6.5 billion times more massive than the Sun. This picture was the first direct visual evidence of a supermassive black hole and its shadow. The ring is brighter on one side because the black hole is rotating, and thus material on the side of the black hole turning toward Earth has its emission boosted by the Doppler effect. The shadow of the black hole is about five and a half times larger than the event horizon, the boundary marking the black hole's limits, where the escape velocity is equal to the speed of light. Created from data collected in 2017, this picture was released in 2019.

supermassive black hole (SMBH), a black hole more than one hundred thousand times the mass of the Sun. Nearly every large galaxy has a supermassive black hole at its centre. Active galactic nuclei, such as Seyfert galaxies and quasars, are powered by supermassive black holes. The largest supermassive black hole is in the galaxy cluster Abell 1201 and has a mass thirty billion times that of the Sun. Sagittarius A*, the supermassive black hole at the centre of the Milky Way Galaxy, has a mass four million times that of the Sun.

The discovery of supermassive black holes was a consequence of the investigation of quasars in the mid-20th century. In the earliest surveys of the sky at radio wavelengths in the 1950s, many radio sources were found to coincide with previously known galaxies, but some coincided with blue starlike objects, which sometimes had fuzzy halos. These objects were called “quasi-stellar radio sources,” or quasars for short.

Observations of the quasar 3C 273 by the Dutch American astronomer Maarten Schmidt showed that the quasars were the most distant objects known and thus brighter than any known galaxy. Quasars were also observed to vary in brightness over a period of days, which meant that they were actually extremely small. Since a quasar is so compact and so luminous, the radiation pressure inside it must be huge; indeed, the only way a quasar can keep from blowing itself up with its own radiation is if it is very massive—at least a million solar masses if it is not to exceed the Eddington limit, the minimum mass at which the outward radiation pressure is balanced by the inward pull of gravity. Quasars represented a previously unknown kind of object, one that was roughly the size of the solar system but with a mass a million times that of the Sun and brighter than a galaxy.

Shortly after Schmidt’s discovery, the mechanism powering quasars—accretion of matter by gravity onto supermassive black holes—was independently proposed by Russian astronomers Yakov Zel’dovich and Igor Novikov and Austrian American astronomer Edwin Salpeter. By 1965, scientists had recognized that quasars are part of a much larger population of unusually blue sources, most of which are much weaker radio sources, too faint to have been detected in the early radio surveys. This larger population, having all the properties of quasars except extreme radio luminosity, became known as “quasi-stellar objects,” or simply QSOs. Since the early 1980s most astronomers have regarded QSOs as the high-luminosity variety of an even larger population of “active galactic nuclei,” or AGNs. (The lower-luminosity AGNs are known as Seyfert galaxies, named after the American astronomer Carl K. Seyfert, who first identified them in 1943.) Each of these objects contains a supermassive black hole.

As matter falls toward the supermassive black hole, it forms an accretion disk because the matter being accreted possesses rotational, or angular, momentum sufficient to prevent it from simply falling inward toward the accretor along a straight line. Matter within the disk spirals inward because it loses energy and angular momentum due to turbulence and viscosity. Because the disk material has to lose energy to accrete onto the central object, the material gets hot, and the heat generated escapes through both sides of the disk. The temperatures in the accretion disks reach up to several million kelvins. Therefore, the disk emits light from infrared to X-ray wavelengths.

Supermassive black holes formed in the early universe and have evolved together with galaxies since then. Exactly how such black holes formed is unknown, but their growth must have been rapid, since supermassive black holes have been observed in objects that formed about one billion years after the big bang.

The Editors of Encyclopaedia BritannicaThis article was most recently revised and updated by Erik Gregersen.