PHYSICS.—Ames:General Physics. Ames and Bliss:Manual of Experiments. Hoadley:Measurements in Magnetism and Electricity. Preston:Theory of HeatandTheory of Light. Poynting and Thomson:Heat. Tyndal:Light. Schuster:Theory of Optics. Barker:Physics. Merrill:Theoretical Mechanics. Helmholtz:Sensations of Tone. Kapp:Electric Transmission of Energy. Crocker:Electric Lighting. Sewell:Elements of Electrical Engineering. Jackson:Elements of Electricity and MagnetismandAlternating Currents and Alternating Current Machinery.
CHEMISTRY.—Remsen:Introduction to the Study of ChemistryandInorganic Chemistry. Roscoe:Lessons in Elementary Chemistry. Wurtz:Elements of Modern Chemistry. Ostwald:Inorganic Chemistry. Alexander Smith:Laboratory Outline of General ChemistryandGeneral Inorganic Chemistry. Wiley:Chemistry of FoodsandAgricultural Chemistry. Roscoe and Schorlemmer:Treatise on Chemistry. Watts:Dictionary of Chemistry. Thorp:Industrial Chemistry.
(Abridged in the Concise Edition.)
ITS STRUCTURE—ORGANIZATION INTO SYSTEMS—FUNCTIONS—SPECIAL SENSES—NERVOUS SYSTEM—PERSONAL HYGIENE—PREVENTION OF DISEASE—INTERDEPENDENCE OF BODY AND MIND—EUGENICS—ILLUSTRATIONS AND CHARTS.
⁂Books of Reference.—Morris:Treatise on Anatomy. Gray:Anatomy. Davidson:Human Body and Health. Martin:Human Body. Huxley and Youmans:Elements of Physiology and Hygiene. Wilson:The Cell in Development and in Inheritance. Thomson:Heredity. Loeb:Comparative Physiology of the Brain and Comparative Psychology. Sternberg:Manual of Bacteriology.
(Abridged in the Concise Edition.)
BIOGRAPHICAL CHART SHOWING THE WORLD’S MASTERS OF ACHIEVEMENT BY CENTURIES.
CHRONOLOGICAL DICTIONARY OF BIOGRAPHY: (a)The World’s Immortals, specially treated; (b)Present-Day Biographies.
(The Biographical Chart only is included in theConciseedition.)
⁂Books of Reference.—Philips:Dictionary of Biographical Reference. Vincent:Dictionary of Biography. Thomas:Dictionary of Biography. Appleton:Dictionary of American Biography;Dictionary of National Biography;Who’s Who in Great Britain;Who’s Who in America. Ruoff:Masters of Achievement;American Statesmen Series;American Men of Letters;English Statesmen Series;English Men of Letters. Smith:Dictionary of Christian Biography.
(Omitted in the Concise Edition.)
PLAYLAND—STORYLAND—NATURE-LAND—SCHOOL-LAND: SIMPLE LESSONS ABOUT WORDS, READING, WRITING, NUMBERS, ETC.—MANNERS AND CONDUCT—THE PARENT AND CHILD—THE OUTLOOK UPON LIFE—EDUCATION AND MORAL GROWTH—CARE OF THE BODY.
⁂Books of Reference.—PRIMARY EDUCATION.—Arnold:Rhythms. Barnard:Kindergarten and Child-Culture Papers. Blow:Educational Issues;Letters to a Mother;Symbolic Education. Froebel’s translatedMother-Play Songs. Froebel:Education of Man;Education by Development;Last Volumes of Pedagogics;Pedagogics of the Kindergarten. Hailman:Laws of Childhood. Harrison:A Study of Child-Nature;Kindergarten Building Gifts;Misunderstood Children;Two Children of the Foothills. Hughes:Educational Laws. Peabody:Kindergarten Lectures. Snider:Commentary on Froebel’s Mother-Play Songs;Life of Froebel;Psychology of the Play-Gifts. Vanderwalker:The Kindergarten in American Education. Von Bulow:The Child;Reminiscences of Froebel.
(Abridged in the Concise Edition.)
Marvels of the Earth’s Rotation and Forces
Proud Color Beauties of the Land of Flowers
Three Celebrated Pictures of Animal Favorites
Washington, America’s City Beautiful
Architectural Glories of Famous Lands
Famous Historical Pictures by Oriental Artists
Tennyson’s Beautiful “Lady of Shalott”
“Open Sesame!” Ali Baba at the Cave
Picture Diagrams of Eye and Ear
The Fiery Furnace that Purifies Bessemer Steel
“The Ides of March”
Famous Masterpieces by Famous Painters
(Only six Color Plates are included in the single volume edition)
Color Diagram Showing the Ocean Beds
Diagram of Orbits of the Planets
Picture Diagram of the Moon’s Phases
Star Charts of the Chief Constellations
Maps of the Chief Constellations
Chart of the Milky Way
Diagrams Showing Formation of Eclipses
Diagram Showing a Bisection of the Earth
Chart Showing the Geological Growth of the Earth
Geological Map of the United States
Maps Showing Relative Size of Islands of the World
Diagram of the World’s Famous Rivers and Mountains
Maps Showing Relative Size of Lakes
Diagrams Explaining the Seasons, Day and Night
Pictorial Chart of Cloud Formations
Map Showing Distribution of Plant Life
Map Showing Range of Animal Life
16 Maps in Color Showing the Progress of Geographical Discovery
2 Picture Maps Presenting a Panoramic View of Paris
5 Picture Maps Giving a Panorama of the River Rhine
Picture Diagram Showing Parts of a Locomotive
Picture Diagram of Submarine
Picture Diagram Explaining Wireless Telegraphy
Picture Diagram Explaining an Electric Battery
Picture Diagram Showing How Electricity is Generated
Picture Diagram Explaining Radioactivity
Map of Panama Canal and Connections
These include hundreds of beautiful and instructive reproductions illustrative of the heavens, earth, minerals, plants and plant products, animal life, races and peoples, famous examples of architecture, scenes in great cities, historic shrines and ruins, mythology, science, marvels of mechanism, great works of engineering, monuments, industries, etc., as well as numerous photographic and art pictures of famous persons and episodes in the history of progress.
THE UNIVERSE: ITS MAGNITUDE AND MEANING
THE SOLAR SYSTEM:Sun,Planets,Moon,Constellations,Stars,Comets,Meteors,Nebulæ, and other Wonders of the Skies
ORIGIN OF THE WORLDS: THE NEBULAR HYPOTHESIS
ECLIPSES: CAUSES AND EXPLANATION
MYTHOLOGY OF THE CONSTELLATIONS
DICTIONARY OF SCIENTIFIC TERMS
STAR CHARTS AND MAPS
NUMEROUS ILLUSTRATIONS AND TABLES
1. Crowded group of stars seen in the constellation Hercules.Solar systemSolar system2. Beautiful circular group of stars in Aquarius. Very brilliant toward the center.3-4. Fan-shaped groups of stars, frequently to be observed.5. Round nebula of Ursa Major.6. A fine star in Gemini with a great, oval atmosphere.7. Star in Leo Major in the middle of nebula with very pointed ends.8-9. Nebulæ with luminous trains like the tail of a comet.10. Two stars in Canes Venatici joined by elliptical nebula.11. Elliptical nebula in Sagittarius with a star in each of the foci.12-13. Round nebula in Auriga with three stars in a triangle.14. Great nebula in Andromeda.15. Comet of 1819, of remarkable size.16-17. Great comet of 1811.18. Surface of the planet Mars, showing the supposed continents and seas.19. Disk of the great planet Jupiter with its dark streaks and masses.20. The wonderful planet Saturn with its remarkable rings.Explanation of Figuresin DiagramDIAGRAM SHOWING RELATIVE ORBITS OF THE PLANETSAROUND THE SUNRate at which thePlanets TravelCentral diagram enlarged(245 kB)Right-hand side illustration enlarged(181 kB)
Central diagram enlarged(245 kB)Right-hand side illustration enlarged(181 kB)
Solar systemDIAGRAM SHOWING RELATIVE ORBITS OF THE PLANETS AROUND THE SUNExplanation of Figures in Diagram1. Crowded group of stars seen in the constellation Hercules.2. Beautiful circular group of stars in Aquarius. Very brilliant toward the center.3-4. Fan-shaped groups of stars, frequently to be observed.5. Round nebula of Ursa Major.6. A fine star in Gemini with a great, oval atmosphere.7. Star in Leo Major in the middle of nebula with very pointed ends.8-9. Nebulæ with luminous trains like the tail of a comet.10. Two stars in Canes Venatici joined by elliptical nebula.11. Elliptical nebula in Sagittarius with a star in each of the foci.12-13. Round nebula in Auriga with three stars in a triangle.14. Great nebula in Andromeda.15. Comet of 1819, of remarkable size.16-17. Great comet of 1811.18. Surface of the planet Mars, showing the supposed continents and seas.19. Disk of the great planet Jupiter with its dark streaks and masses.20. The wonderful planet Saturn with its remarkable rings.Solar systemRate at which the Planets Travel
Solar systemDIAGRAM SHOWING RELATIVE ORBITS OF THE PLANETS AROUND THE SUN
DIAGRAM SHOWING RELATIVE ORBITS OF THE PLANETS AROUND THE SUN
Explanation of Figures in Diagram
1. Crowded group of stars seen in the constellation Hercules.2. Beautiful circular group of stars in Aquarius. Very brilliant toward the center.3-4. Fan-shaped groups of stars, frequently to be observed.5. Round nebula of Ursa Major.6. A fine star in Gemini with a great, oval atmosphere.7. Star in Leo Major in the middle of nebula with very pointed ends.8-9. Nebulæ with luminous trains like the tail of a comet.10. Two stars in Canes Venatici joined by elliptical nebula.11. Elliptical nebula in Sagittarius with a star in each of the foci.12-13. Round nebula in Auriga with three stars in a triangle.14. Great nebula in Andromeda.15. Comet of 1819, of remarkable size.16-17. Great comet of 1811.18. Surface of the planet Mars, showing the supposed continents and seas.19. Disk of the great planet Jupiter with its dark streaks and masses.20. The wonderful planet Saturn with its remarkable rings.
Solar systemRate at which the Planets Travel
Rate at which the Planets Travel
BOOK OF THE HEAVENS
THE UNIVERSE—THE SOLAR SYSTEM—PLANETS—SUN—MOON—CONSTELLATIONS—STARS—COMETS—METEORS—NEBULÆ—NEBULAR HYPOTHESIS—ECLIPSES—MYTHOLOGY OF THE CONSTELLATIONS—DICTIONARY OF SCIENTIFIC TERMS USED IN ASTRONOMY.
HOW THE PLANETS WOULD APPEAR IF GROUPED IN SPACEIn the above picture we have represented the planets of the Solar System as we should see them from the earth if the human eye could grasp a space of such immensity. The spectator is supposed to be standing on the earth, and the moon is in the foreground, 240,000 miles away. The planets are in their order outward from the sun, and vary in distance from 40,000,000 miles, in the case of Mars, to 2,700,000,000 miles in the case of Neptune. From the bottom upward, the planets are Mercury, Venus, Mars, Jupiter, Saturn and its rings, Uranus and Neptune.
HOW THE PLANETS WOULD APPEAR IF GROUPED IN SPACE
In the above picture we have represented the planets of the Solar System as we should see them from the earth if the human eye could grasp a space of such immensity. The spectator is supposed to be standing on the earth, and the moon is in the foreground, 240,000 miles away. The planets are in their order outward from the sun, and vary in distance from 40,000,000 miles, in the case of Mars, to 2,700,000,000 miles in the case of Neptune. From the bottom upward, the planets are Mercury, Venus, Mars, Jupiter, Saturn and its rings, Uranus and Neptune.
The earth upon which we live is only one of many worlds that whirl through space. If we are to understand our own world, we must first learn something about the worlds in the skies. These bodies are arranged in groups, or systems, sweeping through circuits that baffle measurement; and such is the magnitude of the boundless space they occupy that our entire solar system is only a point in comparison. To this vast expanse of worlds, and systems and space we give the general nameUniverse.
First in importance to us in this immense space filled with stars is what astronomers call the Solar System, so-called because the sun is its center. It contains the planets, eight in number, of which our earth is one. They have been named after the ancient deities; the two interior ones, Mercury and Venus, and the exterior ones, Mars, Jupiter, Saturn, Uranus, and Neptune; the first three being smaller than our earth, and the remainder a great deal larger.
Mercury and Venus are known to beinteriorplanets, that is, planets between us and the sun, because they appear to swing on either side of the sun. Mercury very seldom leaves the sun sufficiently to rise so early before the sun, or set so late after him, as to be visible. Venus, however,gets so far away as to be seen long after sunset or before sunrise, and is called the Evening or Morning star, accordingly.
Besides the planets there are other members of the system, namely,cometsandfalling stars, which will be mentioned again more fully hereafter. All these bodies form a sort of family, having the sun for their head. The illustrations and drawings on separate pages give a view of the entire system.
Comparative Size. The size of the planets, in general, increases with their distance from the sun. The four composing the first group are all comparatively small, the earth being the largest. Those of the second group are all of great size. Jupiter, the largest, is not less than 1,390 times as large as the earth; but as it is much less dense, the amount of matter it contains is only a trifle more than 337 times that of the earth. All the planets together equal but one seven-hundredth part of the mass of the sun.
TheSatellites, except our moon, and the two satellites of Mars, belong wholly to the second group of planets. Jupiter has eight; Saturn eight and several revolving rings; Uranus has four, and possibly more; while Neptune, so far as known with certainty, has but one.
Rotary Motion. The sun, all the primary planets, and their satellites, as far as known, rotate from west to east. Each rotation constitutes a day for the rotating body. The central line of rotary motion is called the axis of rotation, and the extremities of the axis are called the Poles.
Revolution Around the Sun. All the primary planets and asteroids revolve around the sun in the direction of their rotation, that is from west to east; and the planes of the orbits in which they revolve coincide very nearly with the plane of the sun’s equator. One revolution around the sun constitutes the year of a planet.
All the satellites, except those of Uranus and perhaps Neptune, also revolve from west to east.
Most of the comets revolve around the sun in very irregular and elongated orbits, only a few having their entire orbit within the planetary system. Some so move that after having entered our system and made their circuit around the sun, they seem to leave it, never to return.
Zodiac
Large illustration(258 kB)
Since the orbits of the planets are in most cases not far removed from the plane of the ecliptic, they are to be seen in a comparatively narrow belt of the heavens called,
The Zodiac. The belt of the sky which occupies 8° on each side of the ecliptic is called the Zodiac, and it is within this belt that the moon and the chief planets confine their movements, as none of their orbits is inclined to that of the earth by more than 8°. The Zodiac, which circles the celestial sphere, is divided into twelve signs each of which occupies 30°, and roughly coincides[15]with a constellation. The following lists give the signs of the Zodiac, with the seasons in which the sun passes through each of them:
Spring: Aries the Ram; Taurus the Bull; Gemini the Twins.
Summer: Cancer the Crab; Leo the Lion; Virgo the Virgin.
Autumn: Libra the Balance; Scorpio the Scorpion; Sagittarius the Archer.
Winter: Capricornus the Goat; Aquarius the Water-bearer; Pisces the Fishes.
Owing to the precession of the equinoxes, the signs of the Zodiac do not now correspond with the constellations of which they bear the names. Thus the sign Aries, in which the sun is seen on March 21st as it passes the vernal equinox, with which the solar year begins, is now in the constellation of Pisces, and in the course of the next 23,000 years it will move steadily backward through the constellations until it returns to the Ram, where it stood when its name was first given to it.
The laws under which the planets move were discovered through the genius of John Kepler, and are known as Kepler’s Laws of Planetary Motion. Kepler derived these laws from observation only, but Newton first explained them by showing that they were the necessary consequences of the laws of motion and the law of universal gravitation.
Kepler’s First Lawstates: “The earth and the other planets revolve in ellipses with the sun in one focus.”
Kepler’s Second Lawstates: “The radius vector of each planet moves over equal areas in equal times.”
Kepler’s Third Lawstates: “The squares of the periodic times of the planets are in proportion to the cubes of their mean distances from the sun.”
DIAGRAMS ILLUSTRATING KEPLER’S FIRST TWO LAWS OF PLANETARY MOTIONThe diagram on the top illustrates the ellipse, and explains the first and second laws. The picture-diagram on the bottom illustrates the second law, which is that, as the planet moves round the sun, its radius vector describes equal areas in equal times. That is to say, a planet moves from A to B in the same time as it takes to move from C to D.
DIAGRAMS ILLUSTRATING KEPLER’S FIRST TWO LAWS OF PLANETARY MOTION
The diagram on the top illustrates the ellipse, and explains the first and second laws. The picture-diagram on the bottom illustrates the second law, which is that, as the planet moves round the sun, its radius vector describes equal areas in equal times. That is to say, a planet moves from A to B in the same time as it takes to move from C to D.
These laws cannot be fully understood without some acquaintance with mathematics. They may, however, be briefly explained for the comprehension of the non-mathematical reader. The figure in thediagramis an ellipse—what is known in popular language as an oval—which is symmetrical about the line AB, known as its major axis. It has two foci, S and S1. The fundamental law of the ellipse is that if we take any point P on it, and join this point by a straight line to the two foci, then the sum of these two lines SP and S1P is always the same—SP + S1P = C.
The second law is rather less easy to understand. Theradius vectoris the line joining the sun to the planet at any moment; if we suppose the sun to be at the focus S, and P to be the planet, the radius vector at various positions of the planet will be represented by the lines SP, SP1, SP2, and so on. If the positions P, P1, P2, and so on, represent those which the planet occupies after equal periods of time—say, once a month—then the sectors of the ellipse bounded by each pair of lines, SP and SP1, SP1and SP2, will be equal. If a planet were to move in a circle round the sun, it is obvious that this law would imply that it moved with a uniform speed; but since the curvature of the ellipse varies in every part of its course, so must the speed of the planet, in order that its radius vector may describe equal areas in equal times. The planet will, in fact, be moving faster when it is near the sun, as at P, than when it is far off from the sun, as at P2.
The third law shows that there is a definite numerical relation between the motions of all the planets, and that the time which each of them takes to complete its orbit depends upon its distance from the sun.
On his discovery of his third law Kepler had written: “The book is written to be read either now or by posterity—I care not which; it may well wait a century for a reader, as God has waited six thousand years for an observer.” Twelve years after his death, on Christmas Day, 1642, near Grantham, England, the predestined “reader” was born. The inner meaning of Kepler’s three laws was brought to light by Isaac Newton.
The great luminary which warms, lights, and rules the solar system is, like the majority of its fellow stars, a gigantic bubble. In other words, it is a globe ofglowing gas, which is nowhere solid, though the immense pressure which must exist in its interior probably causes this gas to assume there a density greater than that of any solid which we know.
A PHOTOGRAPH OF THE SUN, SHOWING THE CLOUDS OF FIERY VAPOR WHICH SURROUND IT
A PHOTOGRAPH OF THE SUN, SHOWING THE CLOUDS OF FIERY VAPOR WHICH SURROUND IT
Dimensions of the Sun.The sun appears to human vision as a brilliant globe of a little more than half a degree in diameter. It is about the same apparent size as the moon, since the size of the sun is to that of the moon very nearly in the same proportion as their relative distances from the earth. In reality, however, the sun is a gigantic orb, so huge that if the earth were at its center the whole orbit of the moon would lie well within its circumference. The diameter of the sun is about 866,500 miles.
The mass of the sun is about 332,000 times that of the earth, but its specific gravity is only about a quarter that of the earth, 1.41, if that of water be taken as unity. The mean distance of the sun from the earth is about 92,800,000 miles; but, as the earth’s orbit is not circular but elliptic, this distances varies by about 3,000,000 miles, being smallest in January and greatest in July.
The Physical Conditionof the sun is very different from that of the earth, though we know it is composed of very similar materials. The white-hot surface that we see, called thephotosphere, is believed to be largely a shell of highly heated metallic vapors surrounding the unseen mass beneath. Dark spaces seen in the photosphere are known assun-spots,and these are often surrounded by brighter patches, termedfaculæ. Above the photosphere a shallow envelope of gases, rising here and there into huge prominences, and known as thechromosphere, is seen in red tints when the sun is totally eclipsed. Beyond the chromosphere, there is also seen, at the same time, a faint but far more extensive envelope called thecorona.
This diagram illustrates the theory that sun-spots are formed by fragments struck from Saturn’s rings (which are in themselves nothing more than a great meteoric swarm) by the swarm of meteors known as the Leonids, which fragments fall into the solar furnace at a speed of four hundred miles a second.
This diagram illustrates the theory that sun-spots are formed by fragments struck from Saturn’s rings (which are in themselves nothing more than a great meteoric swarm) by the swarm of meteors known as the Leonids, which fragments fall into the solar furnace at a speed of four hundred miles a second.
The sun’s rays supply light and heat not only to the earth, but also to theother planets which revolve round it. Its attraction confines these planets in their orbits and controls their motions.
The Moon, the satellite of the earth, is the nearest to us of all the heavenly bodies, being at a mean distance of 240,000 miles. Its diameter is 2,153 miles and, its density being little more than half that of the earth, the force of gravity at its surface is very much less than that at the surface of the earth. A body which weighs a pound here would only weigh about two and one-half ounces if taken to the moon.
THE SYSTEM OF MARS AND ITS MOONS CONTRASTED WITH THAT OF THE EARTH AND MOONIn this diagram the markings on the earth and Mars are to scale, the orbits of the planets are seen in perspective and the measurements are according to Prof. Percival Lowell.
THE SYSTEM OF MARS AND ITS MOONS CONTRASTED WITH THAT OF THE EARTH AND MOON
In this diagram the markings on the earth and Mars are to scale, the orbits of the planets are seen in perspective and the measurements are according to Prof. Percival Lowell.
The Moon’s Orbit.Her path is approximately an ellipse with the earth in one focus. Its apparent motion in the sky is from west to east, but she moves much faster than the sun, taking about twenty-seven days eight hours to travel all round the earth. The time between two successive new moons (synodic period or lunation) is twenty-nine and one-half days. The reason of the difference is that the sun moves slowly in his annual course through the stars in the same direction as the moon, which therefore in its revolution round the earth has to overtake him when it returns. The moon rotates on its axis in the same time as it performs a revolution in its orbit; hence the same half is always turned toward us.
When the moon in her orbit lies between the sun and the earth, she is said to be inconjunctionwith the sun; when the earth is between the moon and the sun, the moon is said to be inoppositionto the sun. At either of the two points midway from conjunction and opposition, i. e. 90° from conjunction or opposition, the moon is said to be inquadrature.
The Phases of the Moon.Except at opposition—i. e. when the earth is between the moon and sun—the whole of the moon’s disc does not appear bright to us, and the amount of the bright surface seen by us is found to depend on the relative positions of moon and sun. Half of the moon is always illuminated by the sun; but when it is in conjunction between the earth and sun the whole of the bright surface is on the side away from us; so that the moon is invisible. As it moves farther from the line joining earth and sun, a small portion of the bright side comes into view as a narrow crescent. This increases till half the disc is illuminated, when the lines joining earth and moon and earth and sun are at right angles. From this time the moon loses its crescent shape and becomes convex on both sides, or gibbous (Lat.gibbus, a hump)—the maximum brightness, or full moon, occurring when sun and moon are on opposite sides of theearth. After this the moon becomes gibbous, then crescent, and vanishes before the time of new moon.
It is worthy of note that the moon is higher in the heavens and longer above the horizon in the winter than in summer. This is owing to the plane of its orbit being at night high towards the south in winter and low in summer, as is the ecliptic. The moon’s orbit, like that of other planets, is elliptical, but irregular. When nearest to the earth, she is said to be inperigee; when at the greatest distance, inapogee.
DIAGRAM SHOWING HOW THE MOON’S PHASES ARE CAUSEDIn the above diagram, the earth is in the center, and the circle ACFH the orbit of the moon. Since the inclination of the plane of the moon’s orbit to the plane of the ecliptic is only a few degrees, we may neglect it in this case, and suppose the two planes to coincide. Let the sun lie in the direction ES. Since the distance of the sun from the earth is about three hundred and eighty-seven times the distance of the moon from the earth, the lines ES, HS, BS, etc., drawn to the sun from different points of the moon’s orbit, may be considered to be sensibly parallel. Let us first suppose the moon to be in conjunction with the sun at the point A. Here only the dark portion of the moon is turned towards the earth, and the moon is therefore invisible. This is called new moon. As the moon moves on towards B, the enlightened part begins to be visible, and when it reaches C, half the enlightened part is visible, and the moon is at its first quarter. When the moon is at F, in opposition to the sun, all the illuminated part is turned towards the earth, and the moon is full. The moon wanes after leaving F, passes through its last quarter at H, and finally becomes again invisible at A.
DIAGRAM SHOWING HOW THE MOON’S PHASES ARE CAUSED
In the above diagram, the earth is in the center, and the circle ACFH the orbit of the moon. Since the inclination of the plane of the moon’s orbit to the plane of the ecliptic is only a few degrees, we may neglect it in this case, and suppose the two planes to coincide. Let the sun lie in the direction ES. Since the distance of the sun from the earth is about three hundred and eighty-seven times the distance of the moon from the earth, the lines ES, HS, BS, etc., drawn to the sun from different points of the moon’s orbit, may be considered to be sensibly parallel. Let us first suppose the moon to be in conjunction with the sun at the point A. Here only the dark portion of the moon is turned towards the earth, and the moon is therefore invisible. This is called new moon. As the moon moves on towards B, the enlightened part begins to be visible, and when it reaches C, half the enlightened part is visible, and the moon is at its first quarter. When the moon is at F, in opposition to the sun, all the illuminated part is turned towards the earth, and the moon is full. The moon wanes after leaving F, passes through its last quarter at H, and finally becomes again invisible at A.
Surface of the Moon.The moon is an opaque, cold globe, covered with mountains, extinct volcanoes, and plains. She has neither water nor atmosphere, and always presents the same surface to the earth in consequence of rotating on her axis in the same time as she revolves round the earth. Moonlight is only reflected sunlight, the illuminated hemisphere being always turned towards the sun.
The face of the moon has been studied and mapped on a large scale. Its chief features are three in number: (1) thenumerousvolcanic craters, such as Tycho and Copernicus, which are mostly named after distinguished men of science; (2) the wide, dark plains which are known asseas, because they were formerly thought to consist of water; (3) the curious systems ofbright streaks, which radiate from many of these craters, of which the most remarkable extend in all directions from the great crater Tycho, near the moon’s south pole, and are conspicuous even to the naked eye at the time of full moon.
The Moon and the Tides.The moon has long been known to have an effect upon the tides, and may perhaps influence the winds. It is of enormous importance to navigators for the determination of longitude, and hence its movements have been investigated with the greatest care and precision.
HOW THE MOON FORMS “TIDES” IN THE CRUST OF THE EARTHBy reason of its power of attraction, it is well recognized that the Moon exercises a greater influence on the side of the earth which is nearest to it. In consequence the earth is subject to a stress or pull that tends to lengthen it out toward the moon, and then to recede as the earth turns away on its axis.
HOW THE MOON FORMS “TIDES” IN THE CRUST OF THE EARTH
By reason of its power of attraction, it is well recognized that the Moon exercises a greater influence on the side of the earth which is nearest to it. In consequence the earth is subject to a stress or pull that tends to lengthen it out toward the moon, and then to recede as the earth turns away on its axis.
The Planet Mars.Nearest to the earth, with the single exception of Venus, resembles the earth more closely than any other of the planets, and is most favorably situated for our observation of all the heavenly bodies, except the moon. It is a globe rather more than half the size of the earth. When Mars comes nearest to the earth its distance from us is about 35,000,000 miles. At these favorable moments its brightness is about equal to Jupiter, and only surpassed by that of Venus. Mars has a very pronounced red color, which is supposed to be due to the prevalence of a rock like our red sandstone on its surface, or possibly to the color of its vegetation.
Its density is much less—about three-quarters that of the earth; so a pound weight placed on its surface would not weigh much more than six ounces, and a ponderous elephant would, if there, be able to jump about with the agility of a fawn.
The heat and light which Mars receives from the sun, therefore, vary enormously, and so cause a difference in the lengths of winter and summer in his north and south hemispheres, the seasons in the north hemisphere being far more temperate than those in the south. Viewed with the telescope, large dark green spots are seen, the rest of the surface being of a ruddy tint, except at the two poles, where two white spots are observed and considered to be due to large masses of snow and ice. It has been supposed that the greenish spots are oceans, and the ruddy parts land. The spectroscope has shown that watery vapor is present in Mars’ atmosphere, and appearances like huge rain-clouds sometimes obscure a part of the planet for a considerable period. Physical processes seem to go on there much the same as on our planet; hence many believe that Mars is inhabited and forms, in fact, a miniature picture of the earth.
Jupiter.By far the largest of the planets is second in brilliancy to Venus, unlike which, however, it is a “superior” planet, having its orbit outside that of the earth. It is about five times as brilliant as Sirius, the brightest of the fixed stars.
The planet is a beautiful object when viewed with a telescope; it is probable that the markings are entirely due to its atmosphere, and that the actual surface of the planet is rarely visible. Jupiter has hardly yet cooled from the condition of incandescence, and it is only slightly solidified. It possesses eight satellites, four of which were discovered by Galileo when he applied the telescope first to the investigation of the heavens. By means of these satellites the first observations of the velocity of light were made. A fifth was discovered in 1892 at the Lick Observatory.
Saturnwas recognized as a planet by the ancients, and was the outside member of the solar system as known by them. His diameters at the equator and poles differ considerably, the protuberance at the equator giving him there a diameter of 74,000 miles, while at the poles it is only 68,000. In size Saturn is the largest of the planets except Jupiter, being in fact seven hundred times larger than our earth, but his density is so small that he would be able to float on water far more easily than an iceberg. From this it follows that he cannot consist of solid or liquid matter, and in fact we can only view a mass of clouds intensely heated within, the whole being probably a planet in the early stage of development—younger even than Jupiter.
The most remarkable characteristic of Saturn, which makes him an object of such interest in the sky, is his possession of a luminous ring. The ring is only luminous on account of its reflection of the sun’s light; hence is invisible to us when, for instance, we are endeavoring to look at the ring from below while the sun is shining above. It also sometimes happens that the plane of the rings passes through the sun or through the center of the earth, in which case only the thin edge of the rings can be seen. The ring is divided into two parts, the inner being the wider, while another faint division appears to divide the outer part into two smaller rings. In 1850 another ring was discovered; this is quite different from the outer rings, being dark, and generally known as the dusky ring of Saturn. The outer ones, though far from solid, can receive a shadow of Saturn, and themselves cast one on his disc. The rings are not continuous masses of matter, but consist of countless myriads of tiny satellites, so close together that to the observer they appear as one body. The planet has eight satellites which seldom pass behind or in front of the planet’s disc, and therefore are not objects of great interest.
Uranusis the next planet beyond Saturn. His mass is about fifteen times as much as that of the earth, an amount which makes him more than outweigh Mercury, Venus, the Earth, and Mars combined. All astronomers do not agree in their estimation of these numbers, Uranus being too far away for measurements to be more than approximate. Gravity on his surface is only three-quarters of what it is here. Uranus has four satellites, and possibly faint rings like those which encircle Saturn.
Neptuneis farthest from the sun, the distance between the two bodies being about 2,750,000,000 miles. At this immense distance it will, according to Kepler’s laws, take a long time to travel once around its orbit, and this time has been found to be one hundred and sixty-five of our years. Although it is ninety-seven times as large as the earth, yet, on account of its enormous distance from us it can only just be seen, even with a powerful telescope. Neptune possesses one satellite, which moves around the planet in rather less than six days.
Mercuryis the smallest planet, except the planetoids, in the solar system, and the one nearest the sun. It is never seen for more than two hours before sunrise or after sunset, and is not always visible then; but when it does appear, it is extremely brilliant. Even when it is most distant the sun appears four and a half times as big to it as it does to us, and when the two are at their nearest, this small planet gets ten times as much light and heat as we do. It is, however, so small and difficult to observe, that comparatively little is known of it.
Venusappears to us as the most brilliant of all the planets, sometimesheralding the sun’s approach in the morning and sometimes following him at night. Hence she has been called the “morning” and the “evening” star; and the ancient Greeks, believing her to be two bodies, and not one, called her Hesperus (Vesper) when she appeared at night, but Phosphorus when she preceded the dawn, this last name having been translated in the Latin, Lucifer. We know very little of the actual surface of Venus, for her envelope of clouds remains constantly in front of us to baffle curiosity, and never lifts to give us a glimpse of the planet beneath. These clouds send on to us the light they borrow from the sun, and shine to us with a brilliant silvery lustre interrupted here and there with shadowy markings of short duration. But when Venus shines to us in crescent-form, certain spots near the ends of the horns can be seen more definitely, and the effects of light and shadow round these points suggest that they are lofty peaks, reaching above the clouds.
The Minor Planets or Asteroids. The space between Mars and Jupiter is occupied by a strange and numerous swarm ofminor planetsorasteroids. The first of these singular bodies was discovered by an Italian astronomer, Piazzi, on the first night of the nineteenth century. Three others were discovered within the course of the next seven years, and the number now known is upward of 600, most of which have been recognized by the record of their motion on photographs of the sky. The four asteroids first discovered, Ceres, Pallas, Juno, and Vesta, are naturally the largest, ranging in diameter from four hundred to one hundred and eighteen miles.
Vesta, though not the largest, is considerably the brightest of the minor planets, and is occasionally visible to the naked eye. None of the other asteroids has a diameter so great as one hundred miles, and probably the majority of them are only ten or twenty miles in diameter.
In addition to the planets and their satellites, the sun is attended by numerous other bodies, moving with far less regularity, and generally much less conspicuous in the heavens. These are known ascometsandmeteoritesorshooting stars. One of the most interesting of recent astronomical discoveries is that an intimate physical connection exists between these two classes of bodies.
Comets.Comets have been known from the earliest times, because every now and then a very large and conspicuous one hastens up to the sun from the remote regions of space, and perplexes monarchs with the fear of change. They are calledcomets, from the Latincoma, meaning hair, because when they are bright enough to be seen with the naked eye they look like stars attended by a long stream of hazy light, which was thought to resemble a woman’s hair flowing down her back. This train of light is known as the comet’stail. Such bright comets are sometimes as brilliant as Venus; their tails have been known to stretch halfway across the visible sky.
These comets are very beautiful and conspicuous objects, which usually appear in the sky without any warning from astronomers, and invariably create a great popular sensation. By far the greater number of comets, however, are only visible through a telescope, and it is rare that a year passes without at least half a dozen of these being reported. Up to the present time nearly a thousand comets of all sizes have been recorded. Not more than one in five of these visitors is visible to the naked eye.
Cometary Orbits.In all cases in which a comet has been observed sufficiently often for its orbit to be calculated, it is found that it moves in one of the curves which are known to the geometer as conic sections. Less than a hundred of the known comets move like the planets inellipticalorbits, and consequently their periodical return to visibility can be predicted. As a rule the eccentricity of these cometary orbits is very much greater than that of any planetary orbit, which means that the comet approaches fairly close to the sun at one end of its orbit, but at the other flies away far beyond the outermost planet, and for a long period disappears from the view of our most powerful telescopes.
The great majority of comets have only been seen once, and their orbits appear to be eitherparabolicorhyperbolic. Neither of these is a closed curve, and what seems to happen in such casesis that a comet travelling in such an orbit dashes up to the sun from the remote parts of space, swings round it, often at very close quarters, and flies away again forever. Only those comets which have elliptical orbits can be said to belong to the solar system. The others are visitors from space, which in the course of their motion come near the sun and are deflected by it, but then fly away until after a lapse of ages they perhaps come within the sphere of another star’s attraction. Of the comets which move in elliptical orbits, about twenty have been observed at more than one return to the sun. Some of these complete their orbits in quite a short period, like Encke’s comet, which has the shortest period of all, less than three and a half years; the longest periodical comet is known as Halley’s, which returns to the sun after seventy-six years, and last appeared in 1910; it is a bright and conspicuous object.
The Constitution of Comets.The nature of comets was long in doubt, and even today their physical characteristics are not fully understood. They are certainly formed of gravitational matter, because they move in orbits which are subject to the same laws as those of the planets. But they also appear to be acted upon by powerfulrepulsive forcesemanating from the sun, to which is due the remarkable phenomenon of cometary tails. Perhaps there is not much exaggeration in the statement once made by a well-known astronomer that the whole material of a comet stretching halfway across the visible heavens, if properly compressed, could be placed in a hatbox. The old fear that the earth might suddenly be annihilated by a comet striking it is thoroughly dispelled by modern investigation, which leads us to believe that the worst results of such an encounter would be an extremely beautiful display of shooting stars.
Meteors, orFireballs, are bodies which do not belong to the earth, but come from other parts of space into our atmosphere, and are seen as bright balls of fire crossing the sky, with a train of light behind. Suddenly they are seen to go out, and very often a fall of stones occurs. Sometimes they are observed to break in two, and loud explosions like thunder are heard. They move very fast—ten or twelve miles per second, and are visible when between forty and eighty miles above the earth.
Other meteors dart across the sky and disappear, all in a very short time. These are known as shooting stars, and are sometimes big and bright, like planets. It is estimated that about six or eight meteors which drop stones come into our atmosphere every year; but some 20,000,000 of small bodies pass through the air every day—these would all appear as shooting stars if they occurred at night.
At some periods of the year there are so many shooting stars that they appear like a shower of fire. On November 14th this happens, the shower being greatest every thirty-three years. A stream of meteors is travelling round the sun, and every thirty-three years the earth just comes through them. Meteoric showers also occur about August 9th to 11th, and smaller ones in April.
The luminosity of meteors is due to the intense heat caused by the resistance of the air to their passage, and in support of this theory it is found that meteoric stones are always covered, either wholly or in part, with a crust of cement that has recently been melted.
We shall now study the so-called fixed stars, those stars, namely, which preserve the same relative position and configuration from night to night, only varying, and that with perfect regularity, in the times at which they reach the meridian. For this reason they have been known from the dawn of astronomy as fixed stars, in contrast with the planets or wandering stars.
The observer who watches the nightly changes in the sky with close attention will soon perceive that all these fixed stars appear to move in circles or parts of circles. Some of them describe larger circles than others, and the further south a star is when it passes the meridian, the larger circle will it describe.
It cannot be too often repeated that this motion of the stars is only apparent, being due to the real rotation of the earth, along with the observer on its surface, in the contrary direction. It is estimated that there are about three thousand stars visible to the naked eyein our latitude, though not all these are visible at the same time, many of them being below the horizon, while others are elevated in the sky at different times and seasons.
In beginning our study of the stars, let us put ourselves in the position of the earliest observers. Let us first, like them, watch the stars, and see how they appear from night to night.
We see, at the first glance, that the stars vary much in brightness. The brightest ones—like Sirius, Capella, Arcturus, and Vega—are called stars of thefirst magnitude. Those less brilliant, like the six brightest of “the Dipper,” are said to be of thesecondmagnitude. All the stars which can be seen with the unaided eye are thus divided into six classes ormagnitudes, according to their brightness.
Constellations.We also see that the stars are not uniformly distributed over the sky. They seem to be arranged in groups, some of which take the form of familiar objects. Every one knows the seven bright stars which are called “the Dipper.” Another group resembles asickle, another across, and so on. All the stars in the heavens have been divided into groups called constellations. Many of these were recognized and named at a very early period.
We should become familiar with these constellations in order to study the stars with any profit.
It is necessary, in the first place, to have some way of designating the stars in each constellation. Many of the brighter stars have proper names as Sirius, Arcturus, and Vega; but the great majority of them are marked by the letters of the Greek alphabet. The brightest star in each constellation is called α (alpha); the next brightest, β (beta); the next, γ (gamma); and so on. The characters and names of the Greek alphabet are as follows:
These letters are followed by the Latin name of the constellation. Thus Aldebaran is called α Tauri; Rigel, β Orionis; Sirius, α Canis Majoris.
If there are more stars in a constellation than can be named from the Greek alphabet, the Roman alphabet is used in the same way; and when both alphabets are exhausted, numbers are used.
Circumpolar Constellations.One of the most important constellations, and one easily recognized, is the Great Bear, or Ursa Major. It is represented inPlate 1on the Star Chart. It may be known by the seven stars forming “the Dipper.” The Bear’s feet are marked by three pairs of stars. These and the star in the nose can be readily found by means of the lines drawn on the chart. It may be remarked here, that in all cases the stars thus connected by lines are the leading stars of the constellation. The stars α and β are called the Pointers. If a line be drawn from β to α, and prolonged about five times the distance between them, it will pass near an isolated star of the second magnitude known as the Pole Star, or Polaris. This is the brightest star in the Little Bear, or Ursa Minor (Plate 2). It is in the end of the handle of a second “dipper,” smaller than the one in the Great Bear.
On the opposite side of the Pole Star from the Great Bear, and at about the same distance, is another conspicuous constellation, called Cassiopeia. Its five brightest stars form an irregular W, opening towards the Pole Star (Plate 2).
About half-way between the two Dippers three stars of the third magnitude will be seen, the only stars at all prominent in that neighborhood. These belong to Draco, or the Dragon. The chart will show that the other stars in the body of the monster form an irregular curve around the Little Bear, while the head is marked by four stars arranged in a trapezium. Two of these stars, β and γ, are quite bright. A little less than half-way from Cassiopeia to the head of the Dragon is a constellation known as Cepheus, five stars of which form an irregular K.
These five constellations never set in our latitude, and are called circumpolar constellations.
Constellations Visible in September.At this time the Great Bear will be low down in the northwest, and the Dragon’s head nearly in the zenith. If we draw a line from ζ to η of the Great Bear and prolong it, we shall find that it will pass near a reddish star of the first magnitude. This star is called Arcturus, or α Boötis, since it is the brightest star in the constellation Boötes. Of its other conspicuous stars, four form a cross. These and the remaining stars of the constellation can be readily traced with the aid ofPlate 3.
Near the Dragon’s head (Plate 4) may be seen a very bright star of the first magnitude, shining with a pure white light. This star is Vega, or α Lyræ.
If we draw a line from Arcturus to Vega (Plate 3), it will pass through two constellations, the Crown, or Corona Borealis and Hercules. The former is about one-third of the way from Arcturus to Vega, and consists of a semicircle of six stars, the brightest of which is called Alphecca or Gemma Coronæ,—“the gem of the crown.”
Hercules is about half-way between the Crown and Vega. This constellation is marked by a trapezoid of stars of the third magnitude. A star in one foot is near the Dragon’s head; there is also a star in each shoulder, and one in the face.
Just across the Milky Way from Vega (Plate 5) is a star of the first magnitude, called Altair, or α Aquilæ. This star marks the constellation Aquila, or the Eagle, and may be recognized by a small star on each side of it. These are the only important stars in this constellation.
In the Milky Way, between Altair and Cassiopeia (Plate 4), there is a large constellation called Cygnus, or the Swan. Six of its stars form a large cross, by which it will be readily known. α Cygni is often called Deneb. It forms a large isosceles triangle with Altair and Vega.
Low down in the south, on the edge of the Milky Way (Plate 6), is a constellation called Sagittarius, or the Archer. It may be known by[25]five stars forming an inverted dipper, often called “the Milk-dipper.” The head is marked by a small triangle. The other stars, as seen by the map, may be grouped so as to represent a bow and an arrow.