The Milky Way and Beyond (25 page)

All nebulae observed in the Milky Way Galaxy are forms of interstellar matter. Their appearance differs widely, depending not only on the temperature and density of the material observed but also on how the material is spatially situated with respect to the observer. Their chemical composition, however, is fairly uniform. It corresponds to the composition of the universe in general in that approximately 90 percent of the constituent atoms are hydrogen and nearly all the rest are helium, with oxygen, carbon, neon, nitrogen, and the other elements together making up about two atoms per thousand.

On the basis of appearance, nebulae can be divided into two broad classes: dark nebulae and bright nebulae. Dark nebulae appear as irregularly shaped black patches in the sky and blot out the light of the stars that lie beyond them. They are very dense and cold molecular clouds; they contain about half of all interstellar material. Typical densities range from hundreds to millions (or more) of hydrogen molecules per cubic centimetre. These clouds are the sites where new stars are formed through the gravitational collapse of some of their parts. Most of the remaining gas is in the diffuse interstellar medium, relatively inconspicuous because of its very low density (about 0.1 hydrogen atom per cubic cm) but detectable by its radio emission of the 21-cm line of neutral hydrogen.

Bright nebulae appear as faintly luminous glowing surfaces; they either emit their own light or reflect the light of nearby stars. They are comparatively dense clouds of gas within the diffuse interstellar medium. They have several subclasses: (1) reflection nebulae, (2) H II regions, (3) diffuse ionized gas, (4) planetary nebulae, and (5) supernova remnants.

Reflection nebulae reflect the light of a nearby star from their constituent dust grains. The gas of reflection nebulae is cold, and such objects would be seen as dark nebulae if it were not for the nearby light source.

H II regions are clouds of hydrogen ionized (separated into positive H
⁺
ions and free electrons) by a neighbouring hot star. The star must be of stellar type O or B, the most massive and hottest of normal stars in the Galaxy, in order to produce enough of the radiation required to ionize the hydrogen.

Diffuse ionized gas, so pervasive among the nebular clouds, is a major component of the Galaxy. It is observed by faint emissions of positive hydrogen, nitrogen, and sulfur ions (H
⁺
, N
⁺
, and S
⁺
) detectable in all directions. These emissions collectively require far more power than the much more spectacular H II regions, planetary nebulae, or supernova remnants that occupy a tiny fraction of the volume.

Planetary nebulae are ejected from stars that are dying but are not massive enough to become supernovae—namely, red giant stars. That is to say, a red giant has shed its outer envelope in a less-violent event than a supernova explosion and has become an intensely hot star surrounded by a shell of material that is expanding at a speed of tens of kilometres per second. Planetary nebulae typically appear as rather round objects of relatively high surface brightness. Their name is derived from their superficial resemblance to planets—i.e., their regular appearance when viewed telescopically as compared with the chaotic forms of other types of nebula.

Supernova remnants are the clouds of gas expanding at speeds of hundreds or even thousands of kilometres per second from comparatively recent explosions of massive stars. If a supernova remnant is younger than a few thousand years, it may be assumed that the gas in the nebula was mostly ejected by the exploded star. Otherwise, the nebula would consist chiefly of interstellar gas that has been swept up by the expanding remnant of older objects.

In 1610, two years after the invention of the telescope, the Orion Nebula, which looks like a star to the naked eye, was discovered by the French scholar and naturalist Nicolas-Claude Fabri de Peiresc. In 1656 Christiaan Huygens, the Dutch scholar and scientist, using his own greatly superior instruments, was the first to describe the bright inner region of the nebula and to determine that its inner star is not single but a compact quadruple system.

Early 18th-century observational astronomers gave high priority to comet seeking. A by-product of their search was the discovery of many bright nebulae. Several catalogs of special objects were compiled by comet researchers; by far the best known is that of the Frenchman Charles Messier, who in 1781 compiled a catalog of 103 nebulous, or extended, objects in order to prevent their confusion with comets. Most are clusters of stars, 35 are galaxies, and 11 are nebulae. Even today many of these objects are commonly referred to by their Messier catalog number; M20, for instance, is the great Trifid Nebula, in the constellation Sagittarius.

By far the greatest observers of the early and middle 19th century were the English astronomers William Herschel and his son John. Between 1786 and 1802 William Herschel, aided by his sister Caroline, compiled three catalogs totaling about 2,500 clusters, nebulae, and galaxies. John Herschel later added to the catalogs 1,700 other nebulous objects in the southern sky visible from the Cape Observatory in South Africa but not from London and 500 more objects in the northern sky visible from England.

The catalogs of the Herschels formed the basis for the great
New General Catalogue
(
NGC
) of J.L. Dreyer, published in 1888. It contains the location and a brief description of 7,840 nebulae, galaxies, and clusters. In 1895 and 1908 it was supplemented by two
Index Catalogues
(
IC
) of 5,386 additional objects. The list still included galaxies as well as true nebulae, for they were often at this time still indistinguishable. Most of the brighter galaxies are still identified by their NGC or IC numbers according to their listing in the
New General Catalogue
or
Index Catalogues
.

The advent of photography, which allows the recording of faint details invisible to the naked eye and provides a permanent record of the observation for study of fine details at leisure, caused a revolution in the understanding of nebulae. In 1880 the first photograph of the Orion Nebula was made, but really good ones were not obtained until 1883. These early photographs showed a wealth of detail extending out to distances unsuspected by visual observers.

Much can be learned about the physical nature of an astronomical object by studying its spectrum—i.e., the resolution of its light into different wavelengths (or colours). Study of the spectrum of an object provides a decisive test as to whether it is composed of unresolved stars (as are galaxies) or glowing gas. Stars radiate at all wavelengths, almost always with dark absorption lines superimposed, while hot, transparent gas clouds radiate only emission lines at certain wavelengths characteristic of their constituent gases. In 1864 observation of the spectrum of the Orion Nebula showed bright emission lines of glowing gases, with conspicuous hydrogen lines and some green lines even brighter. By contrast, the spectrum of galaxies was found to be stellar, so a distinction between galaxies and nebulae—that nebulae are gaseous and galaxies are stellar—was appreciated at this time, although the true sizes and distances of galaxies were not demonstrated until the 20th century.

The 20th century witnessed enormous advances in observational techniques as well as in the scientific understanding of the physical processes that operate in interstellar matter. In 1930 a German optical worker, Bernhard Schmidt, invented an extremely fast wide-angled camera ideal for photographing faint extended nebulae. Photographic plates became progressively more sensitive to an ever-widening range of colours, but photography has been completely replaced by photoelectric devices. Most images are now recorded with so-called charge-coupled devices (CCDs) that act as arrays of tiny photoelectric cells, each recording the light from a small patch of sky. Modern CCDs consist of square arrays of up to 4,000 cells on each side, or 16 million independent photocells, capable of observing the sky simultaneously. Electronic detectors are up to 100 times more sensitive than photography, can record a much wider range of light levels, and are sensitive to a much wider range of wavelengths, from
0.1 micrometre (3.93700787 × 10
^-6
inch) in the ultraviolet (accessible only from satellites orbiting above Earth's atmosphere) to more than 1.2 micrometres (4.72440945 × 10
^-5
inch) in the infrared.

Spacecraft allow the observation of radiation normally absorbed by Earth's atmosphere: gamma and X-rays (which have very short wavelengths), far-ultraviolet radiation (with wavelengths shorter than about 0.3 micrometre [1.18110236 × 10
^-5
inch], below which atmospheric ozone is strongly absorbing), and infrared (from about 3 micrometres to 1 mm [.00012 inches to .039 inch]), strongly absorbed by atmospheric water vapour and carbon dioxide. Gamma rays, X-rays, and ultraviolet radiation reveal the physical conditions in the hottest regions in space (extending to some 100 million kelvins in shocked supernova gas). Infrared radiation reveals the conditions within dark cold molecular clouds, into which starlight cannot penetrate because of absorbing dust layers.

The primary means of studying nebulae is not by images but by spectra, which show the relative distribution of the radiation among various wavelengths (or colours for optical radiation). Spectra can be obtained by means of prisms (as in the earlier part of the 20th century), diffraction gratings, or crystals, in the case of X-rays. A particularly useful instrument is the echelle spectrograph, in which one coarsely ruled grating spreads the electromagnetic radiation in one direction, while another finely ruled grating disperses it in the perpendicular direction. This device, often used both in spacecraft and on the ground, allows astronomers to record simultaneously a wide range of wavelengths with very high spectral resolution (i.e., to distinguish slightly differing wavelengths). For even higher spectral resolution astronomers employ Fabry-Pérot interferometers. Spectra provide powerful diagnostics of the physical conditions within nebulae. Images and spectra provided by Earth-orbiting satellites, especially the Hubble Space Telescope, have yielded data of unprecedented quality.