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The mutual revolution of the giant star and the black hole causes the material falling toward the black hole to spiral around it rather than flow directly into it. The infalling gas whirls around the black hole in a pancake of matter called an accretion disk . It is within the inner part of this disk that matter is revolving about the black hole so fast that internal friction heats it up to X-ray–emitting temperatures (see [link] ).
Another way to form an accretion disk in a binary star system is to have a powerful stellar wind come from the black hole’s companion. Such winds are a characteristic of several stages in a star’s life. Some of the ejected gas in the wind will then flow close enough to the black hole to be captured by it into the disk ( [link] ).
We should point out that, as often happens, the measurements we have been discussing are not quite as simple as they are described in introductory textbooks. In real life, Kepler’s law allows us to calculate only the combined mass of the two stars in the binary system. We must learn more about the visible star of the pair and its history to ascertain the distance to the binary pair, the true size of the visible star’s orbit, and how the orbit of the two stars is tilted toward Earth, something we can rarely measure. And neutron stars can also have accretion disks that produce X-rays, so astronomers must study the properties of these X-rays carefully when trying to determine what kind of object is at the center of the disk. Nevertheless, a number of systems that clearly contain black holes have now been found.
Because X-rays are such important tracers of black holes that are having some of their stellar companions for lunch, the search for black holes had to await the launch of sophisticated X-ray telescopes into space. These instruments must have the resolution to locate the X-ray sources accurately and thereby enable us to match them to the positions of binary star systems.
The first black hole binary system to be discovered is called Cygnus X-1 (see [link] ). The visible star in this binary system is spectral type O. Measurements of the Doppler shifts of the O star’s spectral lines show that it has an unseen companion. The X-rays flickering from it strongly indicate that the companion is a small collapsed object. The mass of the invisible collapsed companion is about 15 times that of the Sun. The companion is therefore too massive to be either a white dwarf or a neutron star.
A number of other binary systems also meet all the conditions for containing a black hole . [link] lists the characteristics of some of the best examples.
| Some Black Hole Candidates in Binary Star Systems | |||
|---|---|---|---|
| Name/Catalog Designation As you can tell, there is no standard way of naming these candidates. The chain of numbers is the location of the source in right ascension and declination (the longitude and latitude system of the sky); some of the letters preceding the numbers refer to objects (e.g., LMC) and constellations (e.g., Cygnus), while other letters refer to the satellite that discovered the candidate—A for Ariel, G for Ginga, and so on. The notations in parentheses are those used by astronomers who study binary star system or novae. | Companion
Star Spectral Type |
Orbital
Period (days) |
Black Hole
Mass Estimates ( M Sun ) |
| LMC X-1 | O giant | 3.9 | 10.9 |
| Cygnus X-1 | O supergiant | 5.6 | 15 |
| XTE J1819.3-254 (V4641 Sgr) | B giant | 2.8 | 6–7 |
| LMC X-3 | B main sequence | 1.7 | 7 |
| 4U1543-475 (IL Lup) | A main sequence | 1.1 | 9 |
| GRO J1655-40 (V1033 Sco) | F subgiant | 2.6 | 7 |
| GRS 1915+105 | K giant | 33.5 | 14 |
| GS202+1338 (V404 Cyg) | K giant | 6.5 | 12 |
| XTE J1550-564 | K giant | 1.5 | 11 |
| A0620-00 (V616 Mon) | K main sequence | 0.33 | 9–13 |
| H1705-250 (Nova Oph 1977) | K main sequence | 0.52 | 5–7 |
| GRS1124-683 (Nova Mus 1991) | K main sequence | 0.43 | 7 |
| GS2000+25 (QZ Vul) | K main sequence | 0.35 | 5–10 |
| GRS1009-45 (Nova Vel 1993) | K dwarf | 0.29 | 8–9 |
| XTE J1118+480 | K dwarf | 0.17 | 7 |
| XTE J1859+226 | K dwarf | 0.38 | 5.4 |
| GRO J0422+32 | M dwarf | 0.21 | 4 |
After an isolated star, or even one in a binary star system, becomes a black hole , it probably won’t be able to grow much larger. Out in the suburban regions of the Milky Way Galaxy where we live (see The Milky Way Galaxy ), stars and star systems are much too far apart for other stars to provide “food” to a hungry black hole. After all, material must approach very close to the event horizon before the gravity is any different from that of the star before it became the black hole.
But, as will see, the central regions of galaxies are quite different from their outer parts. Here, stars and raw material can be quite crowded together, and they can interact much more frequently with each other. Therefore, black holes in the centers of galaxies may have a much better opportunity to find mass close enough to their event horizons to pull in. Black holes are not particular about what they “eat”: they are happy to consume other stars, asteroids, gas, dust, and even other black holes. (If two black holes merge, you just get a black hole with more mass and a larger event horizon.)
As a result, black holes in crowded regions can grow, eventually swallowing thousands or even millions of times the mass of the Sun. Ground-based observations have provided compelling evidence that there is a black hole in the center of our own Galaxy with a mass of about 4 million times the mass of the Sun (we’ll discuss this further in the chapter on The Milky Way Galaxy ). Observations with the Hubble Space Telescope have shown dramatic evidence for the existence of black holes in the centers of many other galaxies. These black holes can contain more than a billion solar masses. The feeding frenzy of such supermassive black holes may be responsible for some of the most energetic phenomena in the universe (see Active Galaxies, Quasars, and Supermassive Black Holes ). And evidence from more recent X-ray observations is also starting to indicate the existence of “middle-weight” black holes, whose masses are dozens to thousands of times the mass of the Sun. The crowded inner regions of the globular clusters we described in Stars from Adolescence to Old Age may be just the right breeding grounds for such intermediate-mass black holes.
Over the past decades, many observations, especially with the Hubble Space Telescope and with X-ray satellites, have been made that can be explained only if black holes really do exist. Furthermore, the observational tests of Einstein’s general theory of relativity have convinced even the most skeptical scientists that his picture of warped or curved spacetime is indeed our best description of the effects of gravity near these black holes.
The best evidence of stellar-mass black holes comes from binary star systems in which (1) one star of the pair is not visible, (2) the flickering X-ray emission is characteristic of an accretion disk around a compact object, and (3) the orbit and characteristics of the visible star indicate that the mass of its invisible companion is greater than 3 M Sun . A number of systems with these characteristics have been found. Black holes with masses of millions to billions of solar masses are found in the centers of large galaxies.
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