Beyond Our Solar System
Beyond Our Solar System begins with an examination of the intrinsic properties of stars-distance, brightness, color, and temperature. Binary star systems, stellar mass, and the Hertzsprung-Russell diagram are discussed in detail. Also investigated are the various types of nebulae. Stellar evolution, from birth through protostar, main-sequence, red giant, burnout and death, is presented. Following stellar evolution are descriptions of the various stellar remnants-dwarf stars, neutron stars, and black holes. The chapter continues with a detailed discussion of the Milky Way galaxy and a general description of types of galaxies, galactic clusters, and red shifts. The chapter closes with a commentary on the origin of the universe and the Big Bang theory.
Learning Objectives
After reading, studying, and discussing this chapter, you should be able to:
•Discuss the principle of parallax and explain how it is used to measure the distance to a star.
•List and describe the major intrinsic properties of stars.
•Describe the different types of nebulae.
•Describe the most plausible model for stellar evolution and list the stages in the life cycle of a
star.
•Describe the possible final states that a star may assume after it consumes its nuclear fuel and
collapses.
•List and describe the major types of galaxies.
•Describe the Big Bang theory of the origin of the universe.
Chapter Summary
•One method for determining the distance to a star is to use a measurement called stellar parallax, the extremely slight back-and-forth shifting in a nearby star's position due to the orbital motion of Earth. The farther away a star is, the less its parallax. A unit used to express stellar distance is the light-year, which is the distance light travels in one Earth year-about 9.5 trillion kilometers (5.8 trillion miles).
•The intrinsic properties of stars include brightness, color, temperature, mass, and size. Three factors control the brightness of a star as seen from Earth: how big it is, how hot it is, and how far away it is. Magnitude is the measure of a star's brightness. Apparent magnitude is how bright a star appears when viewed from Earth. Absolute magnitude is the "true" brightness if a star were at a standard distance of about 32.6 light-years. The difference between the two magnitudes is directly related to a star's distance. Color is a manifestation of a star's temperature. Very hot stars (surface temperatures above 30,000 K) appear blue; red stars are much cooler (surface temperatures generally less than 3000 K). Stars with surface temperatures between 5000 and 6000 K appear yellow, like the sun. The center of mass of orbiting binary stars (two stars revolving around a common center of mass under their mutual gravitational attraction) is used to determine the mass of the individual stars in a binary system.
•A Hertzsprung-Russell diagram is constructed by plotting the absolute magnitudes and temperatures of stars on a graph, A great deal about the sizes of stars can be learned from H-R diagrams. Stars located in the upper-right position of an H-R diagram are called giants, luminous stars of large radius. Supergiants are very large. Very small white dwarf stars are located in the lower-central portion of an H-R diagram. Ninety percent of all stars, called main sequence stars, are in a band that runs from the upper-left corner to the lower-right corner of an H-R diagram.
•Variable stars fluctuate in brightness. Some, called pulsating variables, fluctuate regularly in brightness by expanding and contracting in size. When a star explosively brightens, it is called a nova. During the outburst, the outer layer of the star is ejected at high speed. After reaching maximum brightness in a few days, the nova slowly returns in a year or so to its original brightness.
•New stars are born out of enormous accumulations of dust and gases, called nebula, that are scattered between existing stars. A bright nebula glows because the matter is close to a very hot (blue) star. The two main types of bright nebulae are emission nebulae (which derive their visible light from the fluorescence of the ultraviolet light from a star in or near the nebula) and reflection nebulae (relatively dense dust clouds in interstellar space that are illuminated by reflecting the light of nearby stars). When a nebula is not close enough to a bright star to be illuminated, it is referred to as a dark nebula.
•Stars are born when their nuclear furnaces are ignited by the unimaginable pressures and temperatures in collapsing nebulae. New stars not yet hot enough for nuclear fusion are called protostars. When collapse causes the core of a protostar to reach a temperature of at least 10 million K, the fusion of hydrogen nuclei into helium nuclei begins in a process called hydrogen burning. The opposing forces acting on a star are gravity trying to contract it and gas pressure (thermal nuclear energy) trying to expand it. When the two forces are balanced, the star becomes a stable main-sequence star. When the hydrogen in a star's core is consumed, its outer envelope expands enormously and a red giant star, hundreds-to-thousands of times larger than its main-sequence size, forms. When all the usable nuclear fuel in these giants is exhausted and gravity takes over, the stellar remnant collapses into a small dense body.
•The final fate of a star is determined by its mass. Stars with less than one-half the mass of the sun collapse into hot, dense white dwarf stars. Medium-mass stars (between 0.5 and 3.0 times the mass of the sun) become red giants, collapse, and end up as white dwarf stars, often surrounded by expanding spherical clouds of glowing gas called planetary nebulae. Stars more than three times the mass of the sun terminate in a brilliant explosion called a supernova. Supernovae events can produce small, extremely dense neutron stars, composed entirely of subatomic particles called neutrons; or even smaller and more dense black holes, objects that have such immense gravity that light cannot escape their surface.
•The Milky Way galaxy is a large, disk-shaped, spiral galaxy about 100,000 light-years wide and about 10,000 light-years thick at the center. There are three distinct spiral arms of stars, with some showing splintering. The sun is positioned in one of these arms about two-thirds of the way from the galactic center, at a distance of about 30,000 light-years, Surrounding the galactic disk is a nearly spherical halo made of very tenuous gas and numerous globular clusters (nearly spherically shaped groups of densely packed stars).
•The various types of galaxies include 1) spiral galaxies, which are typically disk-shaped with a somewhat greater concentration of stars near their centers, often containing arms of stars extending from their central nucleus, 2) barred spiral galaxies, a type of spiral galaxy that has the stars arranged in the shape of a bar, which rotates as a rigid system, 3) elliptical galaxies, the most abundant type, which have an ellipsoidal shape that ranges to nearly spherical, and lack spiral arms, and 4.) irregular galaxies, which lack symmetry and account for only 10 percent of the known galaxies.
•Galaxies are not randomly distributed throughout the universe. They are grouped in galactic clusters, some containing thousands of galaxies. Our own, called the Local Group, contains at least 28 galaxies.
•By applying the Doppler effect (the apparent change in wavelength of radiation caused by the motions of the source and the observer) to the light of galaxies, galactic motion can be determined. Most galaxies have Doppler shifts toward the red end of the spectrum, indicating increasing distance. The amount of Doppler shift is dependent on the velocity at which the object is moving. Because the most distant galaxies have the greatest red shifts, Edwin Hubble concluded in the early 1900s that they were retreating from us with greater recessional velocities than more nearby galaxies. It was soon realized that an expanding universe can adequately account for the observed red shifts.
•The belief in the expanding universe led to the widely accepted Big Bang theory of the origin of the universe. According to this theory, the entire universe was at one time confined in a dense, hot, supermassive concentration. About 20 billion years ago, a cataclysmic explosion hurled this material in all directions, creating all matter and space. Eventually the ejected masses of gas cooled and condensed, forming the stellar systems we now observe fleeing from their place of origin.