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The chief distinguishing feature of the members of a stellar association is that the large majority of constituent stars have similar physical characteristics. An OB association consists of many hot blue-giant stars, spectral classes O and B, and a relatively small number of other objects. A T association consists of cooler dwarf stars, many of which exhibit irregular variations in brightness. The stars clearly must be relatively close to each other in space, though in some cases they might be widely dispersed in the sky and are less closely placed than in the open clusters.

The existence of an OB association is usually established through a study of the space distribution of early O- and B-type stars. It appears as a concentration of points in a three-dimensional plot of galactic longitude and latitude and distance. More than 70 have been cataloged and are designated by constellation abbreviation and number (e.g., Per OB 1 in the constellation Perseus). In terms of dimensions, they are larger than open clusters, ranging from 100 to 700 light-years in diameter, and usually contain one or more open clusters as nuclei. They frequently contain a special type of multiple star, the Trapezium (named for its prototype in Orion), as well as supergiants, binaries, gaseous nebulas, and globules. Associations are relatively homogeneous in age. The best distance determinations are from spectroscopic parallaxes of individual stars—i.e., estimates of their absolute magnitudes made from studies of their spectra. Most of those known are closer than 10,000 light-years, with the nearest association, straddling the boundary between Centaurus and Crux, at 385 light-years.

Associations appear to be almost spherical, though rapid elongation would be expected from the shearing effect of differential galactic rotation. Expansion, which is on the order of 10 km/sec, may well mask the tendency to elongate, and this is confirmed in some. Tidal forces break up an association in less than 10 million years through differences in the attraction by an outside body on members in different parts of the association.

A good example of an OB association is Per OB 1, at a distance of some 7,500 light-years, which spreads out from the double cluster h and χ Persei. A large group of 20 supergiant stars of spectral type M belongs to Per OB 1. Associations with red supergiants may be in a relatively advanced evolutionary stage, almost ready to disintegrate.

The T associations (short for T Tauri associations) are formed by groups of T Tauri stars associated with the clouds of interstellar matter (nebulas) in which they occur. About three dozen are recognized. A T Tauri star is characterized by irregular variations of light, low luminosity, and hydrogen line (H-alpha) emission. It is a newly formed star of intermediate mass that is still in the process of contraction from diffuse matter. The small motions of T Tauri stars relative to a given nebula indicate that they are not field stars passing through the nebula. They are found in greatest numbers in regions with bright O- and B-type stars.

Nicolaus Copernicus. Nicolas Copernicus (1473-1543) Polish astronomer. In 1543 he published, forward proof of a Heliocentric (sun centered) universe. Coloured stipple engraving published London 1802. De revolutionibus orbium coelestium libri vi.
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T associations occur only in or near regions of galactic nebulosity, either bright or dark, and only in obscured regions showing the presence of dust. Besides T Tauri stars, they include related variables, nonvariable stars, and Herbig-Haro objects—small nebulosities 10,000 astronomical units in diameter, each containing several starlike condensations in configurations similar to the Trapezium, Theta Orionis, in the sword of Orion. These objects are considered to be star groups at the very beginning of life.

The constellation of Cygnus has five T associations, and Orion and Taurus have four each. The richest is Ori T2, with more than 400 members; it has a diameter of 50 by 90 light-years and lies at a distance of 1,300 light-years around the variable star T Ori.

Dynamics of star clusters

Seen from intergalactic space, the Milky Way Galaxy would appear as a giant luminous pinwheel, with more than 150 globular clusters dotted around it. The richest parts of the spiral arms of the pinwheel would be marked by dozens of open clusters. If this panorama could be seen as a time-lapse movie, the great globular clusters would wheel around the galactic centre in elliptical orbits with periods of hundreds of millions of years. The open clusters and stellar associations would be seen to form out of knots of diffuse matter in the spiral arms, gradually disperse, run through their life cycle, and fade away, while the Sun pursued its course around the galactic centre for billions of years.

Young open clusters and associations, occupying the same region of space as clouds of ionized hydrogen (gaseous nebulas), help to define the spiral arms. A concentration of clusters in the bright inner portion of the Milky Way between galactic longitudes 283° and 28° indicates an inner arm in Sagittarius. Similarly, the two spiral arms of Orion and Perseus are defined between 103° and 213°, with a bifurcation of the Orion arm. Associations show the existence of spiral structure in the Sun’s vicinity. Older clusters, whose main sequence does not reach to the blue stars, show no correlation with spiral arms because in the intervening years their motions have carried them far from their place of birth.

All the O- and B-type stars in the Galaxy might have originated in OB associations. The great majority, if not all, of the O-type stars were formed and still exist in clusters and associations. Though only 10 percent of the total number of B-type stars are now in OB associations or clusters, it is likely that all formed in them. At the other (fainter) end of the range of stellar luminosities, the number of dwarf variable stars in the nearby T associations is estimated at 12,000. These associations are apparently the main source of low-luminosity stars in the neighbourhood of the Sun.

While large numbers of associations have formed and dispersed and provided a population of stars for the spiral arms, the globular clusters have survived relatively unchanged except for the evolutionary differences that time brings. They are too massive to be disrupted by the tidal forces of the Galaxy, though their limiting dimensions are set by these forces when they most closely approach the galactic centre. Impressive as they are individually, their total mass of 10 million suns is small compared with the mass of the Galaxy as a whole—only about 1/10,000. Their substance is that of the Galaxy in a very early stage. The Galaxy probably collapsed from a gaseous cloud composed almost entirely of hydrogen and helium. About 14 billion years ago, before the last stages of the collapse, matter forming the globular clusters may have separated from the rest. The fact that metal-rich clusters are near the galactic nucleus while metal-poor clusters are in the halo or outer fringes may indicate a nonuniform distribution of elements throughout the primordial mass. However, there is evidence that galaxies are given to cannibalism, in which smaller galaxies merge with larger ones that do not necessarily have the same properties. This has complicated the picture of chemical evolution. The case of the globular cluster Omega Centauri suggests this merging also may happen on smaller scales. Its stars are unusual, perhaps unique, in having a variety of chemical compositions, as though they came from more than one earlier cluster.

In a study of star clusters, a time panorama unfolds—from the oldest objects existing in the Galaxy, the globular clusters, through clusters in existence only half as long, to extremely young open clusters and associations that have come into being since humans first trod Earth.