The Sun and Its Family 0080081959, 9780080081953
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and
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THE SUN and
Its
Family
IRVING ADLER
By
Ruth Adler
Illustidtrd h\
Author and illustrator of The Stars, Magic House of Xumhers, etc.
The
Su)i
(i)i(l
Family
Its
panion volume to The
is
a
com-
Stars: Stepping-
stones Into Space, the latter describing
new book
the stars in general and this
describing the star which together witli
ticular sini,
which we
is
oin- par-
its
faniilv
the solar system.
call
Roth books take an api)roach that them from otlier books on astronomy. Irving Adler does not just describe tlie sun and the planets, how large they are and how far from
distinguishes
ca( h other, etc
.
He
believes that the
reader will understand the solar system niU( M hciUM. hud it iiiu(Ji more intt resting, and retain his information
uuK
h longer,
mastered This
proach.
if
is,
We
in
(
shoit.
i)egin
a juud)le. llie
how mankind
he sees
tlie sid)je(
wa\
the
in
j^hue.
lustorital
a
bv seeing ii
first
inusi
tlie
ap-
sky as
ha\c looked
men. Then we noii( e that most of the stars seem to siav in tlie same |)la{es with resj^ec to each other, while a lew are w.uidereis; and tli.Ji theto primitive
t
.u
(
(.ojilniurd on hack llap)
THE SUN and
f^mrn9ffi€
Its
Family
public jLibrary
Books by Irving Adler
THE SUN AND
ITS
FAMILY
MAN-MADE MOONS
MONKEY BUSINESS: HOAXES IN THE NAME OF SCIENCE
HOW
LIFE BEGAN
MAGIC HOUSE OF NUMBERS THE STARS: STEPPINGSTONES INTO SPACE TOOLS IN YOUR LIFE FIRE IN YOUR LIFE
TIME
IN
YOUR LIFE
THE SECRET OF LIGHT
THE SUN and
Its
Family
By IRVING
ADLER
Illustrated by
Ruth Adler
J A
The John Day Company
New
York
©
1958 BY
IRVING AND RUTH ADLER
All rights reserved. This bcxjk, or parts thereof,
must
not be reproduced in any form without permission.
Pubhshed by The John Day Company, 62 West 45th Street, New York 36, N.Y., and on the same day in Canada by Longmans, Green & Company, Toronto.
Third Impression
Library of Congress Catalogue Card Number: 58-7464
MANUFACTURED
IN
THE UNITED STATES OF AMERICA
Contents
I.
n.
What
Two
We
See in the Sky
Systems: Ptolemy
vs.
9 Copernicus
23
m.
The Earth
IV.
The Earth Revolves Around the Sun
53
The Sun and
67
V.
VI.
vn.
vm.
Our Home,
35
Spins
Its
Family
the Earth
91
Our Nearest Neighbor, The Moon
101
The Other
109
Planets
Index
127
M000JLAMt
WYOMIM0
^
»
THE SUN and
Its
Family
(Sarp^gU public JUibrury
CHAPTER
What We
I
See in the Sky 1.
'_^ Xi- ia/
^
Looks Can Be Deceiving
SCIENTISTS
us that the earth
is
round.
a big ball, they say, about eight thousand miles
It is
wide. is
tell
It is
sailing
spinning around like a merry-go-round, and
through space at a speed of
I8/2
miles per
second, or 66,600 miles an hour. It revolves around the
making a complete round
sun,
time
first
we
trip
every year.
The
hear these facts they are hard to beUeve,
because they do not seem to match the way things look. If we stand outdoors and look around us, what
we
see of the earth doesn't look like a ball at
all.
It
and rock, with a looks more smooth surface where we see plains, and with bumps and wrinkles where we see hills and mountains. We don't feel the earth moving or spinning. In fact, it seems to be standing perfectly still. And when we watch the sun, as it rises in the east, climbs across the sky, and then sets in the west, it looks as though the sun is going around the earth, rather than the other like a flat
way
cake of
soil
around.
But things
aren't always the
way
they seem.
is round, does spin, and does revolve around the For thousands of years this truth was hidden from
earth sun.
The
9
people by misleading appearances. But patient study of the earth and sky finally uncovered the truth and produced evidence that proved it. This book tells the storv of the discoveries that broke
down
false beliefs
about the earth and sun, and led us to an understanding of the real nature of the earth as a
member
of
the sun's family of planets.
A
Puzzle in the Sky
The sky
is
like a great stage.
The
stars,
the sun, the
moon and the planets are the actors that move across it. Day after day and year after year they act out the same play. The scenes we see in the sky today were watched by other people thousands they observed the action
about
its
meaning.
What
is
bright light floods the land
of years ago.
in the sky,
As
they wondered
the sun, they asked, whose
by day? What
is
the moon,
that lights the path of the traveler at night?
What
are the stars that surround the moon, like courtiers
attending a queen in her palace?
Why
are they in the
and why do thev move as thev do? The skv was a puzzle which the people tried to solve. They looked for clues to the puzzle in what they saw in the sky.
skv,
To understand
we must
their attempts to interpret these clues,
begin as they did, by looking at the sky.
The Sky -Sphere
When we
look at the sky on a clear night,
we
see
it
spotted with thousands of tiny lights, twinkling like flickering candles.
bowl
that
10
is
The sky
resting upside
looks like a great black
down, with us inside
it.
The
stars look like spots that
have been painted on
the inside of the bowl.
The
make
one of complete confusion. Some stars look brighter than others. Some parts of the sky are crowded with stars, while, in other parts of the sky, the stars look widely scatfirst
impression the stars
is
tered.
After
we have watched the
are better acquainted with to look less confused.
in the sky that
look at in the
sky for it,
many nights, and
the confusion begins
We notice some regular features
we can
recognize easily every time
we
The stars seem to have a fixed arrangement sky. Our attention is attracted by groups of it.
stars that are
arranged in familiar-looking patterns.
In the northern part of the sky
we
see one group of
11
stars
arranged
in the
not far from
shape of a dipper. Another group,
W.
looks like a great letter
it,
southern part of the sky, in the summertime,
In the
we
see
whose arrangement suggests the out-
a group of stars
Another group of
line of a teapot.
stars close to the
teapot looks like a giant fishhook. In the middle part of the sky
we
see a group that looks like a cross.
The
group keep their places from night to night, and the groups themselves have a fixed arrangement, too. If the stars were really spots painted on the inside of a bowl, they would be permanently painted spots. Each star has its regular place that it seems to keep forever. For this reason, in ancient times, people called them fixed stars. The groups of stars are called stars in a
constellations.
Thousands
of years ago, in all parts of the world,
made up
about the stars and constellations, and gave them names. The stories usually involved the adventures of their gods. Today we don't people
stories
believe these stories, but
the old names.
The
per to us looked So, while call
The
it
we
find
it
convenient to use
constellation that looks like a dip-
like a
we sometimes
bear to the ancient Romans. call
it
the Big Dipper,
Ursa Major, which means Big Bear
constellation that looks like a
peia, the
name
of a
queen who
stories told in ancient Greece.
looks like a teapot
fishhook
is
is
called
W
is
we
in Latin.
called Cassio-
figures in
The group
one of the
of stars that
called Sagittarius, the archer.
Scorpius,
because
also
the
The
ancients
looked like a scorpion. The cross in the middle part of the sky has two common names. It
thought
12
it
known as the Northern Cross, and Cygnus, the swan. is
If
is
also called
we watch the sky for several hours during the we notice another one of its regular features.
night,
While the
stars
constellations
seem
move
fixed in the constellations, the across the sky. They move as
though the whole bowl of the sky were turning, carrying the stars along with it as it turns. There is a fixed point in the northern sky around which it seems to turn, and all the stars move in circles around this point. This fixed point is called the North Pole of the
There
is
a star that
is
sky. so close to this point that it
hardly
seems to move at all as the sky turns. Because this star helps us find the position of the North Pole in the sky,
we
call it Polaris.
13
Stars that are near the horizon in the eastern part
of the sky rise
above the horizon
as the night advances.
As they cUmb up the sky, we see other stars behind them moving up to take their place. This observation forces us to change our picture of what the sky looks like. The way in which more stars keep appearing at the horizon suggests that
we picture
the sky as a sphere
rather than a bowl, with the earth located at the center
We see the upper half of the sphere above us, but the bottom half is hidden by the ground. As the sphere turns, the hidden part is raised up to where we can see it, making its first appearance in the east. Meanwhile stars near the horizon in the west are of the sphere.
carried
down by
the turning sky into the part that
is
hidden by the ground. After about twelve hours, these stars which set in the west rise again in the east. The sky-sphere seems to make one complete turn every day, so that the stars
we can 14
make
see them.
daily trips across the sky
where
The Sun and the Moon The
brightest objects in the sky are the sun
moon. They
also rise in the east
and
and the
set in the west,
only to rise later in the east once more. Like the stars, they repeat their journey across the sky every day. This makes it seem as though the sun and the moon are on the
move
that they ries
them
When
same sky-sphere that as
it
carries the stars,
and
across the sky because the sphere carturns.
the sun
the stars vanish, but the moon many days during each month the moon in the sky in broad day-
rises,
does not. There are
when we can see hght. The moon then
looks paler than
We soon reahze that the moon looks
it
does at night.
pale
by day only
because we see it against the bright background of a daytime sky that is flooded with scattered sunlight.
Then we
realize, too,
daytime.
The same
why
the stars disappear in the
scattered sunlight that
moon look pale by comparison
is
also bright
makes the enough to
cover up the feeble light of the stars completely. stars are still in the
hidden by the bright to verify this fact
The
sky in the daytime, only they are
We get a chance an ecHpse of the sun.
light of the sun.
when
there
is
During an eclipse, the moon passes in front of the sun and blocks off its light. The sky then becomes dark as if it were night, and the stars appear, showing us that they were there all the time behind the curtain of daylight. We can verify it, too, by looking at the sky through a telescope. A powerful telescope can pierce the curtain of daylight and reveal the stars in 15
their places in the sky in the daytime.
Wanderers If the
sun
is
being carried across the sky by the
turning of the sky-sphere, then
we must
think of the
sun as having a definite location among the the sphere.
We
can locate
this
on place on any day by stars
seeing which stars are near the sun, at the eastern horizon,
and
rise
with
it
for these stars again a
in the
week
morning.
later,
we
If
we watch
find that they
about a half hour earlier than the sun does. Two weeks later they rise an hour earlier. This shows that the sun does not stay in one place on the sky-sphere. It moves back steadily from west to east, so that, compared to the movement of the stars across the sky, the sun falls four minutes behind every day. The sun is a wanderer on the sky-sphere. If we observe its wander-
rise
ings for a long time, circle
we
find that
it
travels along a
on the sky-sphere, and completes a round trip The path it follows on the sky-sphere is
in a year.
called the ecliptic.
The moon,
too,
is
a wanderer. In fact,
if
you merely
few hours, vou can see how it shifts its position among the stars. The moon, like the sun, moves across the sky-sphere from west to cast,
watch the moon
for a
going about thirteen times as
fast as the sun.
Like a
on a circular race track, it passes the sun, gets ahead of it, and then overtakes it again from behind. The moon catches up with the sun in this way about every thirty days. Usually, when the moon passes the sun, they merely he fast horse
16
running against a slow
rival
side by side on the sky-sphere. Occasionally, the moon moves right across the spot on the sky-sphere occupied by the sun. When this happens, the moon lies between us and the sun, and there is an eclipse of the sun.
The sun and
the
moon are not alone in their wander-
Thousands of years ago, had people already noticed that there were some "stars" that wandered, too. They didn't look quite like the other stars, either. While all the other stars were just pin points of hght, the wandering "stars" were distinct discs. They followed very pecuhar paths on the sky-sphere, too. While the sun and moon moved along ings across the sky-sphere.
the other wanderers followed paths that
simple
circles,
made
loops. In ancient times people
knew
of five
wanderers besides the sun and the moon. We know them now as the planets Mercury, Venus, Mars, Jupiter,
at
and Saturn, and we know that they
aren't stars
all.
17
The word planet comes from the Greek word meanThe Greeks referred to all the seven
ing wanderer.
wanderers that they knew, including the sun and
moon,
as planets.
Today we use
the
word
in a different
Behind th« screen
way, the
to
mean bodies
word
that revolve around the sun. Using
in this sense, the
sun and the
moon
planets, but Mercury, Venus, Mars, Jupiter
urn
are.
We
also include
among
the planets
are not
and tlie
Sat-
earth
and several bodies that the ancient Greeks never saw because they are too faint to be seen by the naked eye. The new planets, discovered after the telescope was invented, are known as Uranus, Neptune, and Pluto. itself,
18
A Shadow
Play
You have probably seen a shadow play, in which people act out a scene while standing behind a screen.
The audience
doesn't see the actors, but sees their shadows projected on the screen by a light that is behind them. The use of these shadows makes it possible to produce some interesting illusions. For example, if one actor swings a dagger past the body of another, without bringing it near enough to touch him, on the screen it looks as though he is stabbing him in
the back.
On
the
shadow screen the
place where the man's back
is,
because the real knife
passes between the man's back projects both of
them onto the
knife crosses the
and the
light
which
screen.
19
What we a
shadow
round
us.
see on the sky-sphere
is
in
some wavs
like
play. We are looking out at things that surWe see these things as they were projected if
against a screen behind them. As a result, two objects
may seem to be at the same spot on the skv-sphere when they are actually far apart. Thev will seem to be together on the sky-sphere when one passes betv^^een us
and the
other.
Astronomers realized
quite early, as a result of hints they got
this fact
bv watching
the wanderers traveling over the skv-sphere. Every
saw the moon move across by stars. Each time this happened, the stars disappeared on one side of the moon, and then reappeared later on the other. They drew the conclusion that the moon was closer to us than the stars, and blocked a star from view whenever it passed in front of it. During an eclipse of the sun, they could see the moon moving across the face of the sun. This showed tliem that the moon is closer to us than the sun is, and that it sometimes passes between us and the sun. The movements ice see on the sky-sphere are not the real movements of the heavenly bodies. They are only projections, like shadows on a screen. That is why the play we see acted out in the sky is a puzzle. The puzzle is to find out the real positions of the heavenly bodies and the real movements they make, which make them look the way they do on night, for example, they
places on the sphere occupied
the sky-sphere.
The puzzle breaks up
Why things
into
many
separate questions.
does the sky-sphere as a whole, with
we
20
see on
it,
seem
to revolve
around
tlie
all
the
earth?
Why
are the fixed stars fixed
on the sky-sphere, and
why do the wanderers wander? What are these bodies we see in the sky, and how far are they from the earth? We could also ask, "What are they made of?" "How heavy are they?" "How hot are they?" and many, many more questions besides. Modern astronomy has found the answers to a large number of these questions. It solved the puzzle of the fixed stars by showing that every star is really a sun that is very far away. The stars look so tiny because and they seem fixed the same reason. The evidence and the thinking
of their great distance from us, for
that solved the puzzle of the fixed stars are presented in the book. The Stars: Steppingstones into Space."* Astronomy solved the puzzle of the wanderers by show-
ing that the planets are satellites of the sun, each revolving around the sun with a regular rhythm. discoveries
and the thinking that solved
this
The
puzzle
are described in the chapters that follow. •
By
the
same
author.
New
York:
The John Day Company, 1956.
21
CHAPTER
Two
II
Systems:
Ptolemy
vs.
Copernicus
Spheres Within Spheres
THE be much
puzzle of the fixed stars didn't seem to
of a puzzle to the astronomers in ancient
They simply accepted as real what they saw with their own eyes. They saw the fixed stars rising times.
and
though they were in fixed positions on a big sphere that surrounded the earth and rotated around it. So they advanced the theory that there really was such a sphere, and they called it the sphere of the fixed stars. But the wanderers were a Httle more troublesome. Their motion across the sky was more comphcated, and needed in the east
setting in the west, as
a more complicated explanation.
In the
first
place, the astronomers reaUzed that the
wanderers were closer to the earth than the fixed stars were, because they could see them passing between the earth and the stars, blocking the Hght of the stars
when they did
so.
They could
see, too, that
some wanderers were closer to the earth than others. The moon, for example, was closer than the sun, because it sometimes passed in front of the sun and 23
its light. Using clues similar to those which be described in Chapter V, they even made estimates of how far from the earth each of the seven wanderers was. They arranged them in this order, from the nearest to the farthest from the earth: the moon, Mercury, Venus, the sun. Mars, Jupiter, and Saturn. Each of them was assumed to be on a sphere of its own, with one sphere inside the other, and all of the spheres surrounding the earth. Since the wanderers,
eclipsed
will
like the stars, rose daily in the east, crossed the sky,
and
set in the west, the
astronomers advanced the
theory that their spheres, like the sphere of the also rotated
around the earth from east
stars,
to west.
To
account for the fact that the wanderers seemed to move eastward among the stars, they assumed that the spheres carrying the planets turned more slowly
than the sphere carrying the
stars, so that
the planets
kept falling behind.
The theory
were spheres within spheres rotating around the earth left one important set of facts unexplained: Some of the planets sometimes made loops in the sky. To account for the loops it was necessary to change the theory a bit. In the improved theory, the moon and the sun were left on the spheres that were supposed to carry them around the earth, but the other planets were taken off the spheres. Their places were taken by imaginary points, one on each sphere. Each planet itself was supposed to move in a circle around one of these points while the point was carried around the earth by the rotating sphere. These were the ideas we find in the theory of Claudius
24
that there
The Ptolemdic System
/
Ptolemy, the greatest astronomer of ancient times,
who
lived in Alexandria, Egypt, from about a.d. 85 to 165.
Ptolemy's theory of
how
the planets
move
is
shown
diagram on page 25. At the center of the uniwas the earth. The moon and the sun, each carried by its sphere, moved in a circle around the earth. Each of the other wanderers moved in a circle around in the
verse
an imaginary point, called the
fictitious planet,
while
the point was carried along a circle around the earth.
The path followed by the fictitious planet was called The path followed by the real planet as it moved around the fictitious planet was called an epia deferent.
cycle. In Ptolemy's theory,
inside the sun's circle,
Mercury and Venus were
and the
fictitious planets
moved around were always on
they
the line joining the
earth to the sun. Mars, Jupiter and Saturn were out-
and moved so that the line joining each to its fictitious planet was always parallel to the hne joining the earth and the sun. As a planet moved around its epicycle, it spent part of the time outside its deferent, and part of the time inside. While it was outside the deferent, it moved in the same direction as the fictitious planet, caught up with it, and passed it. While it was inside the deferent, it moved in the opposite direction, and fell behind. This alternate passing and falling behind accounted for tlie loops these planets made on the sky-sphere. Although Ptolemy's epicycles served to explain the side the sun's circle,
loops, they failed to explain other irregularities in the
movements of the planets. To make his system fit the facts more closely, Arab astronomers who lived after 26
Ptolemy patched it up by adding epicycles to the epicycles, just as he had added epicycles to the deferents. Before they were through with these changes, they were using over eighty circles to explain the mo-
The Ptolemaic system of wheels within wheels became more comphcated than the inside of a modern watch. In this comphcated form, it was accepted throughout Europe as a true tion of the seven wanderers.
picture of the universe for about fifteen hundred years.
During
these years, although astronomers felt
all
free to change the details of Ptolemy's system in order to try to
of his
improve
main
it,
they insisted on holding onto two
They always placed the
ideas.
earth at
the center of the universe, assuming that the earth
stood
still
while the stars and planets
moved around
it. And they took it for granted that the only paths heavenly bodies could follow were circles. They insisted on placing the earth at the center of the universe
two reasons. First, that is the way things looked when you watched the sky. Everybody could "see" that the stars and the wanderers were revolving around for
fit in with the common God put these bodies in the sky to serve man. Since man was the center of their thoughts, they very naturally made his home, the earth, the center of
the earth. Secondly, the idea
behef that
the universe.
They
insisted
paths for the planets or the
on using only
circles as
fictitious planets,
of the influence of religious ideas.
because
The
planets were were supposed to be perfect. The circle was the most perfect of all curves, they said, so it was the only kind of path that a in heaven,
and
all
things in heaven
27
heavenly body could follow.
A New
Center for the Universe
During the sixteenth century, one of these ideas was challenged by a priest named Nicolas Copernicus. Copernicus, who lived from 1473 to 1543, devoted his life to the study of astronomy. It seemed to him that the Ptolemaic system was far too complicated, and that there was a much simpler explanation for the apparent motion of the stars and planets. He said it was not necessary to believe that
all
the heavenly bodies
revolve around the earth. Their daily motion across the sky could be explained just as well by assuming that the earth
was spinning
at rest. If the earth
is
like a top, instead of
being
spinning from west to east, that
would make it look as though everything around the earth is moving the other way, from east to west. Copernicus also found that he could explain the loops in the paths of the planets across the sky-sphere by assuming that the sun, rather than the earth, was the center of the universe.
He
offered the theory that the
earth, together with Mercury, Venus, Mars, Jupiter,
and Saturn, moved
around the sun. Under this theory, only the moon revolved around the earth. Because he held onto the old idea of circles as the only possible paths, he had to use epicycles, too. But his system used only thirty-four circles while Ptolemy's used over eighty. Hints
From
in circles
the Telescope
At the time when Copernicus proposed
28
his theory,
was no proof that it was more correct than The only thing that was in its favor was that it was simpler. But after the telescope was invented, new facts were discovered that gave hints that Copernicus' theory might be true. These facts were uncovered by the Italian scientist, Galileo Galilei, who lived from 1564 to 1642. Galileo was the first to use a there
Ptolemy's.
telescope for the exploration of the sky.
When
he
looked at the sun through his telescope, he saw some
dark spots on
its
face.
The dark
spots
moved
in a
way
showed that the sun was spinning like a top. Here was a hint that Copernicus was on the right track. If the sun was spinning, then it was possible that the earth might be spinning, too. that
When
Galileo looked at Jupiter through his tele-
saw what looked like faint stars near it. Watching them from day to day, he could see that they were moons of Jupiter, revolving around Jupiter the way our moon revolves around the earth. Here was another hint that Copernicus could be right. The motion of the moons of Jupiter showed that not all scope, he
heavenly bodies revolved around the earth. If there could be bodies revolving around Jupiter, then it was possible that there might be bodies revolving around the sun.
When
he looked
at the
moon through
the
he saw that the moon had mountains. If as the earth did, and if the sun had spots, then it showed that the heavenly bodies were no more perfect than the earth. Here was a third hint that Copernicus might be right. If the heavenly bodies were not perfect, then perhaps they were no telescope,
the
moon had mountains
29
from the
different
earth.
Then the
earth, in spite of all
blemishes, could be a planet, like Mars or Jupiter, revolving around the sun. But these were only hints. its
They showed
that Copernicus
might be
right,
but they
another important discovery
when he
did not prove that he was.
The Phases Galileo
Venus
of
made
turned his telescope on the planet Venus.
moon
does.
then in the gibbous phase,
when
Venus went through phases,
that
In fact, he saw
it
just
He found
as the
more than half of its disc was covered with light. This was clear proof that Ptolemy's theory was wrong. To understand why, let us first see why the moon goes through
its
phases.
The moon does not produce
light of
its
own, as the
by At any moment, only half of the surface of the moon receives any sunlight, because only half of the surface is turned toward the sun. The other half of the moon is dark because it faces away from the sun and lies in the moon's own shadow, as shown in the diagram below. As the moon revolves around the earth, sometimes we see only the sunlit half, sometimes we see only the dark half, and sometimes we see a part of each. The way in which the moon's phases change is shown in the diagram on sun does.
It
strikes
surface.
it
reflecting sunlight that
The moon is shown in several positions that may have as it moves in its orbit. What we see when is in each of these positions is shown by the circles
page it
its
shines only
31.
at the top
30
and bottom
of the diagram.
When
the
moon
between the earth and the sun, the sunht half of the moon faces away from the earth, and we see only the dark half of the moon. Then, as the moon moves to the side, part of the sunht half turns into view. At first we see only a crescent moon. By the time the lies
Light
from the sun
Phases of the
Moon
31
moon
has gone one-fourth of the
way around its moon
the crescent has growTi until half of the
we
orbit,
circle
Then it enters the gibbous phase, when more than half of what we see is covered by light. When the moon reaches the position where the moon and the sun are on opposite sides of the see
is
covered by
light.
earth, the sunlit half of the earth,
moon
faces toward the
and we see a full moon. Then the dark half beview again, and we see less and less
gins to swing into
of the sunlit part until, finally,
when
the
moon
is
be-
tween the earth and the sun again, we see none of the sunlit half at
The that it
it,
all.
fact that \'enus passes too, shines
moves
in
such a
through phases shows
only by reflected sunlight, and that
way
that varying fractions of
its
sun-
lit half face toward the earth. Let us see how this would happen if Ptolemy's theory were correct. The diagram on page 33 shows \^enus moving as Ptolemy thought it did. The fictitious planet around which it
turns, according to Ptolemy, lies
the earth and the sun.
moving
in a circle
Venus
around
on the line that joins supposed to be point. Four possible the diagram. At the
itself is
this
Venus are shown in bottom of the diagram we see what Venus would look like in these positions. In each position, the half of Venus that faces toward the sun is flooded with sunlight. When \'enus is between the earth and the sun, we would see no part of this sunlit side at all. The illuminated part would begin to turn into view only as Venus moved away from the line to the sun. We would see the largest amount of reflected sunlight positions of
32
when Venus reached
the side positions
shown
in the
diagram. But in these positions, more than half of the
sunht side
still
faces
away from the
earth, so that only
a crescent would be seen from the earth. theory were correct,
we would
half of the sunlit side of Venus.
If
Ptolemy's
never see as
much
as
But Gahleo saw more
than half of the sunht side, because he saw Venus in the gibbous phase. This proved that Ptolemy was
wrong.
"ibboos phase
WHAT GALILEO SAW
a,c
Venus as seen from the earth according to Ptolemy
A
Compromise System
The phases of Venus showed that Ptolemy was wrong, but they did not prove that Copernicus was right. Although Copernicus' theory permitted Venus to go through the correct phases, as we can see them in 33
was not the only theory that did. The phases of Venus are explained just as well by the theory of Tycho Brahe, Dutch astronomer who lived from 1546 to 1601. Tycho's theory was a compromise between Ptolemy's theory and Copernicus'. the telescope,
He
it
yielded to Copernicus to the extent of saying that
the planets revolve around the sun. But he stuck
Ptolemy
in his belief that the sun,
by
accompanied by
around the earth. He insisted that and is the center of the universe. But Tycho's compromise didn't last long, because further study of the earth and the sky produced positive evidence that the earth does move. We have definite proofs now that the earth does spin on its axis, and that the earth does revolve around the sun. These proofs, described in the next two chapters, its
planets, revolved
the earth stands
still
finally established
Copernicus' theory as a true pic-
ture of the solar system.
34
CHAPTER
III
The Earth Spins A
Spin Detector
TO PROVE need a spin
detector.
that the earth really spins,
An
we
object can serve as a spin
detector if we know, from the way it works, that it would behave in one way if the earth were not spinning, and would behave in another way if the earth were spinning. Then we can find out whether or not the earth spins by merely watching this object to see which way it behaves. One of the things that can serve as a spin detector
To make string,
is
a swinging 'pendulum.
a pendulum,
and then
tie
tie
a weight to one end of a
the other end to a chandeher or
anything else that can support over the ground.
To
set the
it
while
it
hangs
down
pendulum swinging,
the weight to one side, and then let
pull
Experiments with the pendulum show that if a swinging pendulum is not disturbed, it keeps sunnging back and forth in it
the same plane. This property of the it
go.
pendulum makes
useful as a spin detector.
To try
it
see
how
a
pendulum
serves as a spin detector,
out with a phonograph turntable. First set the
pendulum swinging over the turntable while the turntable is at rest. The plane in which the pendulum 35
swings crosses the turntable along a this line visible
chalk.
As long
by drawing over
as the turntable
is
line. it
We can make
with a piece of
at rest, the
pendulum
keeps swinging back and forth over the chalk
line.
But the behavior of the pendulum looks different if the turntable spins. Then, while the pendulum keeps swinging back and forth in the same plane, the chalk line, carried by the spinning turntable, turns under the pendulum. The pendulum no longer crosses over the same line with each swing. If there were some tiny creature living on the turntable, it would look to him as though the plane of the pendulum were turning. If the turntable turned in the same direction as the hands of a clock, or clockwise, it would look to this creature as though the plane of the pendulum were turning the other way, or counterclockwise.
36
The length
of time that
seem
to
took for the plane of the pendulum to
it
make one complete
length of time that
it
turn would actually be the
took for the turntable to
make
one complete turn. If the creature on the turntable were curious and intelligent, he would reahze that the swinging pendulum could tell him when the turntable was spinning and when it was at rest. If he saw the pendulum cross over the same Hne with each swing, then he would know that the turntable was at rest. But if the plane of the pendulum seemed to turn, then it
would show
that the turntable
was spinning.
We can use the pendulum in the same way as a spin detector for the earth. However, the earth
is
not
flat,
phonograph turntable. It is round, like a ball. This makes the effect of its spinning a little more com-'
like a
plicated, as
we
shall see.
37
If the
Earth Spins
is really spinning, we should be able to by the effect that the spinning has on the motion of a pendulum. But this effect is not the same at all places on the earth's surface, on account of the fact that the earth is shaped like a ball.
If
tell
the earth
that
When
it is
a ball spins like a top around an axis, there
on the axis. On the earth we call these two points the North Pole and the South Pole. The spin of the earth shows up in different ways at the two poles. As seen from a are two points on the surface
38
of the ball that
lie
point above the North Pole, the spinning earth
is
like
a turning phonograph turntable, spinning counterclockwise around the North Pole as center. Because of
plane of a swinging pendulum at the North Pole turns clockwise. Since the earth makes one complete turn in a day, a pendulum there, if it doesn't stop swinging too soon, makes a full turn in twentyfour hours. Down at the South Pole, an observer sees the spinning earth from the other side. As a result, he sees the ground spinning in the opposite direction. At the South Pole the ground spins clockwise, so there this fact, the
the plane of a swinging wise,
pendulum
and makes a complete turn
turns counterclock-
in twenty-four hours,
too.
Halfway between the North Pole and the South Pole
is
the circle around the earth that
we
call the
39
equator.
Here the spinning
other effect.
An
of the earth has
observer looking
down
still
an-
at the earth
from above the equator would see it rolling like a barThe rolling motion carries the ground forward, but
rel.
does not
make
it
turn like a turntable. Since the ground
does not turn there, the plane of a swinging pendulum held at the equator does not turn at
all.
At places between the poles and the equator, the
Here the plane of a swinging pendulum turns, but more slowly than it does at the poles, so that it makes less spinning of the earth has an intermediate
than a
full
effect.
turn in twenty-four hours. In the Northern
Hemisphere it turns clockwise, just as it does at the North Pole. In the Southern Hemisphere, the pendulum turns counterclockwise. Foucault's
Pendulum
The spinning
of the earth
swinging pendulum
in
was
first
detected by a
the year 1851.
The French
Foucault made a pendulum of a heavy iron about a foot wide, attached to a wire that was over 200 feet long. He hung the pendulum from the scientist
ball
dome
of the
in Paris. To be sure pendulum was not influenced
Pantheon building
that the swinging of the
by any accidental pushes, he
set
it
swinging with extra
special care. First he pulled the ball to one side, tied
it
with a
string.
He
left
it
tied for
many
and
hours, to
be sure that it came to rest. Then he released the ball by burning the string, and the pendulum began to swing. The space over which the pendulum swung was surrounded by a rail, and a thin layer of sand was 40
At each swing, the ball of the pendulum passed over the rail, and a pin in the bottom of the ball made a line in the sand. But with each new swing the pin made a new line instead of going over the old ones. The successive lines appeared placed on the top of the
rail.
'""^^^^m^mm^^-
by side going clockwise, showing that the plane of the pendulum was turning in that dii'ection. The rate at which it was turning was enough to carry it side
through a complete turn in 32 hours. Since 1851 experiment has been repeated many times at many ferent places.
Each time the plane
of the
between the equator and one
dif-
pendulum has
turned at a rate that could be predicted from tion
this
its
of the poles.
posi-
These
experiments serve to prove two things at the same time. Besides showing that the
show
that the earth
is
eaHh
really spins, they also
a spinning ball.
41
A
Falling
Body
A body that falls from a great height above can also serve
as a spin detector. If the earth
spinning, a freely falling
down
along the line that joins
its
directly beneath
starting place.
its
it
spinning from west to
not land at the point under stead,
why
it
lands at a point a
this
42
happens,
look
would land
at the point
But because the
east, a falling
body does
starting position. In-
its
little
at
straight
starting place to the
Then
is
were not
body would move
center of the earth.
earth
the earth
further east.
the
diagram
To
see
above.
The letter
em
A marks
a point on the ground in the north-
B marks a point high up above the point A. As the earth spins from west to east, the ground at A and the air at B both travel eastward along circles. These circles are shown in the diagram. Because B is further from the earth's axis than A is, it travels along a larger circle. Both A and B make a complete round trip, each along its own hemisphere. The letter
in the air
circle, in twenty-foin* hours,
earth to
make one complete
greater distance than
B
is
of
two
tends to carry It also
covers a
it
eastward with the speed of the the body is dropped, its motion is
travels
it
Then, when
air at B.
made up
B
means that a body is held
in this time,
Now if
takes the
it
rotation. Since
A does
traveling east faster than A.
in place at B,
it
parts. It has a
downward motion
directly to the point
A
has an eastward motion that
starting place at B.
as
the time that
though the point
ning a race to the
that
on the ground. got from its
it
A also is moving eastward, so it is A and the falling body were runeast.
proaches the ground,
it
But
carries
as the falling
down with
it
body apthe higher
eastward speed of the upper level. This higher speed makes it possible for the falling body to get ahead of the ground and win the race. Instead of landing at A it
lands a bit to the east of A.
happens serves
The Path There
is
The
fact that this actually
as another proof that the earth rotates.
of an Artillery Shell
further proof that the earth rotates in the
effect that the rotation has
from a big gun. Suppose an
on the path of a artillery
gun
shell fired
in the
North-
43
em
Hemisphere is aimed north and fires a shell. If the earth were not spinning, the shell would travel northward, in the direction in which the gun is aimed. But because the earth is spinning, the shell veers toward the east from its course. The reason why this happens is similar to the reason for the eastward drift
The spinning
of a falling body.
of the earth carries
every point on the ground around in a
gram above shows
circle.
The
dia-
that the size of this circle de-
pends on how close the point
is
to the
North Pole.
Points near the pole travel along a smaller circle than points nearer to the equator, and as a result they
When
move
from a gun that is aimed north, the shell has the eastward motion of the place that it starts from. But as the shell travels north, it travels over ground that is moving eastward more slowly. The shell gets ahead of the ground in the eastward more slowly.
race to the east, and so
44
it
a shell
veers to
is
fired
tlie right.
In the Southern Hemisphere the earth's rotation has the opposite
eJBFect.
There, as a shell travels north,
passes over ground that
is
moving eastward
faster than
behind
in the race
the shell does. So here the shell to the east,
and veers
artillery
falls
The earth's rotation way the gun is aimed.
to the left.
has this effect no matter which
When
guns are
fired, this influence of
earth's rotation has to
be taken
The Direction
Wind
The that
it
of the
it
the
into account.
earth's rotation reveals itself, too, in the effect
has on the direction of the wind.
It influences
same way that it influences an artiUery shell. Just as a shell is a moving body of metal aimed from the gun to a target, a wind is a moving body of air aimed from a high-pressure region to a low-pressure region. If the earth were not spinning, the high-pressure region would push the wind directly to the lowthe
wind
in the
45
pressure region. But since the earth
is
spinning,
it
compels the wind to veer from its course. In the Northem Hemisphere, the wind veers to the right. So, in the Northern Hemisphere, when you face in the direction in which the wind blows, the low-pressure region is on your left. In the Southern Hemisphere it would be on your right. This fact is well known to weathermen, and is additional proof that the earth is spinning on its axis.
Cyclones and Hurricanes
The wind rushes in toward a low-pressure region from all directions. If the earth were not rotating, lines showing the direction of the wind near a low-pressure center would look like the spokes of a wheel, as shown 46
in
diagram
veer
1.
But since the earth
diagram
2.
is
spinning, the winds
shown in In the Northern Hemisphere, where they
away from
the low-pressure center, as
low
veer to the right, the result
is
that the winds spiral
around counterclockwise. Weathermen call such a spiraling wind system a cyclone. In the Southern Hemisphere, where the winds veer to the left, the cyclone turns clockwise. The center of a hurricane is a low-pressure region, so the winds of a hurricane spiral in toward it, carrying the storm clouds on their backs. When a hurricane is viewed on a radar screen, the spiral arrangement of the clouds can be seen distinctly. The spiral shape of cyclones and hurricanes is
yet another proof that the earth really spins.
The Gyrocompass
A
rather interesting spin detector
A
^
r^
on
is
made
out of
47
Picture of a hurricane on a radar screen
something that has a spinning motion of its own, and is known as a gyrocompass. The gyrocompass contains a spinning wheel, or gyroscope, and takes advantage of the pecuhar way in which a gyroscope resists any attempt to tilt its axis. The principle on which it operates can be demonstrated by using a bicycle wheel mounted on an axle in such a way that the wheel can
spin freely while the axle
hands.
If,
is
while the wheel
is
grasped firmly in both spinning rapidly, you
try to tilt one end of the axle down, you find that the wheel stubbornly resists being tilted. The resistance takes on an especially interesting form if you repeat the experiment while sitting on a stool whose seat is
49
free to turn, like the counter seats in an ice-cream
Then, while the wheel is spinning rapidly, if you try to tilt one end of the axle down, instead of the wheel tilting, the seat of the stool begins to turn,
parlor.
carrying you and the spinning wheel around with If
you
try to
tilt
it.
the other end of the axle down, the
seat starts turning the other way.
Any attempt
to
tilt
the axis of a spinning gyroscope causes a rotation at right angles to the direction of the tilting force.
is mounted so that its and can swing around in a horizontal plane. An electric motor keeps the wheel spinning steadily on its axis. If the axis points east and west, the rotation of the earth tends to tilt it by tilting the eastem end down and the western end up. The result is
In the gyrocompass, a wheel
axis
is
horizontal,
50
that the axis swings around in the horizontal plane, just as the seat of the stool did in the
experiment with
the bicycle wheel. It keeps swinging around imtil the
down
it swings beyond that The end that was tilted up by the earth's rotation,
north and south.
axis points
position, the effect
before
is
is
now
If
reversed. tilted
so this time the axis swings around the other way.
Because of tles
down
this corrective action,
the axis finally set-
in the north-south position.
By
its
pecuHar
behavior the gyrocompass not only proves that the earth rotates. It also points out
and In
which way
so really serves as a compass, as
fact, it is
its
name
is
north,
suggests.
a better compass than the magnetic com-
because it points out the true position of the North Pole, while the magnetic compass only points to the magnetic north pole, which is not in the same place. It is better, too, because it can be used inside a metal ship, where a magnetic compass is useless because the surrounding metal shields it from the earth's magnetic field. pass,
A
Spin
We Do
Not Feel
Our own bodies are spin detectors, too. We know this from what happens when we ride on a merry-goround. As the merry-go-round spins around, ourselves being pulled it
turns, the stronger
known
away from is
the pull
as the centrifugal force
its
we
center. feel.
we
The
feel
faster
This pull
(force pulling
is
away
from the center) that comes into existence whenever a moving body spins or turns. Because we can feel this force, we can tell when a train we are riding in is 51
rounding a curve. While the train is going around the curve we feel ourselves forced to lean over toward the outside of the curve.
The
proofs described in this chapter
show
that the
earth is turning like a merry-go-round, so there must be a centrifugal force tending to pull us away from the earth's axis, the center around which it turns. In spite of this fact, we do not feel any such pull. Although our bodies are usually good spin detectors, they do not help us detect the spin of the earth. We do not feel the centrifugal force because it is covered up by an even stronger force acting in the opposite direction. This stronger force is our own weight. Our weight is a force that tends to pull us toward the center of the earth.
The
centrifugal force caused
by the
earth's ro-
is not strong enough wipe it out. So we still feel ourselves pulled toward the ground rather than being flung away from it. This is why the spin of the earth is one spin that we do not
tation opposes our weight, but to
feel.
52
CHAPTER
IV
The Earth Revolves
Around Not a Ripple
in
Sun
Your Coffee
TO PROVE we have
the
that the earth revolves around
motion detector, some device that will show whether the earth is traveling through space or is staying in one place. First we have to decide where to look for this motion detector. Can
the sun,
we
find
tion has
that
we
it,
to find a
perhaps, in some effect that the earth's
on
us, or the things
cannot,
and we can
mo-
we do? The answer is why by referring
find out
to our experience with railroad trains.
When
a train
moving and picks up speed, we can feel it because we are thrown back. When the train slows down and stops, we feel it, because then we are thrown forstarts
ward.
When
cause then
the train rounds a curve,
we
are thrown to the side.
we
feel
it,
train travels in a straight line at a steady speed,
don't feel
its
motion
at
all.
be-
But when the
we
In fact, a railroad com-
pany on the Atlantic coast used to boast that its trains gave you such a smooth ride that there was "Not a Ripple in Your Coffee" when you ate in the dining car. Experience shows that we cannot feel steady mo53
We
can only feel a change in the motion, like a change in speed or a change in direction. The earth's
tion.
motion in its orbit around the sun goes on at a steady pace of about 18% miles per second. Because it is steady, we do not feel it. It is true that the motion keeps changing direction, because the orbit is curved. But because the orbit is very large, the change in direction
is
so slow that
we do
The sun cannot be detected by not feel that either.
motion around the it has on us or anything else that is on the earth. To find our motion detector we have to look away from the earth.
earth's
any
effect
The Sun Doesn't Help Since
we
are trying to prove that the earth
around the sun, we may be tempted
moves
to search for the
what we see when we look at the sun. But this will not work either. Again, our experience with railroad trains will explain why. Everybody who has traveled on a train has probably had an experience like this: Your train stops at a station, and there is another train alongside yours, on another track. While you wait impatiently for the train to start again, you watch the faces of the people in the other train. Then, at last, you see that you are moving again. Your train is slowly slipping past the other train. You pass car after car, finally pass the end of the train, and then discover with a shock that your train is not moving at all. It is still standing at the station. It was the other train that was moving, in the opposite direction. You were misled because the effect is the same whether evidence
54
in
your train moves or the other train moves. In both cases you merely see the trains passing each other
and then pulling apart. You can't tell which train is moving until you look away from the trains to the station or the ground.
Our motion around
the sun
is
similar in this respect
motion past each other of two trains. Looking at the sun will not tell us whether the earth is moving around the sun or the sun is moving around the earth.
to the
To
is moving around the sun from look away both bodies.
find proof that the earth
we have
to
The Rain
We
shall find the
ing for falls
of Starlight
by looking
on the earth
motion detector that
we
are look-
at the stars. In the starhght,
which
like a gentle rain, there are several
proofs that the earth revolves around the sun. In fact,
one of the proofs
is
found
in the fact that the rays of
starhght falling on the moving earth behave like rain-
drops falhng past a moving
Suppose you are riding
train.
in a train
on a rainy but
windless day, and you are watching the rain through the car window. Because there
drops is
fall straight
down
at rest at a station,
the raindrops
move
is
no wind, the
to the ground.
you can see across the
When
this fact in
window
rain-
the train
the
pane.
way
Each
raindrop, falling straight down, traces out a vertical line against the shift
when
window
pane. But the rain seems to
the train moves. Then, instead of falling
vertically, the raindrops streak past the
window 55
in
slanting lines, as
Let us see
why
if
they were being blown by a wind.
this
happens.
While the raindrops are falling down past your window, the train is moving forward past the raindrops. The forward motion of the train makes the raindrops
move backward
across the
window
pane,
away from
the front end of the train. This backward motion com-
downward motion of the drops to give slanting path along the window pane. This has
bines with the
them a the
eflFect
of shifting the direction that the raindrops
seem to be coming from. While the raindrops are really coming from directly overhead, the motion of the train makes it look as though they are coming from a place ahead of this overhead position.
The motion
of the earth in
of the stars in the
56
same way
its
orbit affects the light
that the motion of a train
affects the paths of the falling raindrops. It shifts the
direction
from which the
starlight
seems
to
come. This
Hght is known as the aberalways in the direction in which the earth itself is moving. But when the earth revolves around the sun, it keeps changing the direction in which it moves. As a result, the stars seem to shift around on the sky-sphere. Stars that are in the shift in the direction of the
ration of light.
The
shift is
same plane in which the earth's orbit lies seem to move back and forth in a straight line. Stars whose light comes to us at right angles to this plane seem to make httle circles on the sky-sphere. Stars between these two extreme positions trace out little ovals on the skysphere. The amount of the shift is not very great. Whether the stars seem to move in straight lines or circles or ovals, the greatest shift in
seconds of arc on the sky-sphere.
each case
How tiny
is
this is
41 can
be seen from the fact that 60 seconds (of arc) make one minute, 60 minutes make one degree, and 360 degrees
make
a full great circle girdling the sky.
How-
can be detected by modern telescopes and can be measured. ever, although the shift
is
so small,
it
This shift in the position of the stars on the sky-
sphere
is
a motion detector for the earth. It proves
that the earth
us the
rhythm
is
moving around the
sun. It even tells
of that motion, because the
rhythm of
the stars, as they shift around on the sky-sphere,
matches the rhythm with which the earth revolves around the sun. A star that moves around a little oval on the sky-sphere takes a year to make a round trip around the oval. This shows that the earth takes a year
57
to
make
We
its
saw
own round
in
Chapter
I
around the sun. that the sun is a wanderer on trip
moves along the circle known as the echptic, and makes a complete trip around in a year. Now we can understand why it seems to wander in the sky, and why it repeats its wanderings every year. The sky-sphere is like a big curtain against which we see the sun, like the backdrop on a stage against which the sky-sphere.
It
the audience sees the actors in a theater.
When
the
sun seems to move across this curtain it is because the earth itself is moving. As the earth moves around in its orbit, the sun seems to move the other way, just as the trees we pass when we ride by in a train seem to move toward the rear of the train. When the sun takes
a year for a round trip along the ecliptic,
it
another sign that the earth takes a year for
its
trip
The
is
only
round
around the sun. Shifting Colors in Starlight
Starlight
is
a mixture of colors.
The
colors can
be
separated by passing the hght of a star through a
wedge-shaped piece of glass known as a prism. When the starlight emerges from the prism, the colors lie side by side, arranged the way they are in a rainbow, from violet to red. This spread-out arrangement of the colors in the light of a star
is
called
its
spectrum.
colors are bright in the spectrum.
Some
of the
Other colors are
weak, and in contrast to the brighter colors that sur-
round them, they look spectrum.
has
its
58
The dark
own
pattern.
lines
like
dark lines crossing the
form a pattern, and each
star
These dark-line patterns have turned out to be a gold mine of information about the stars. The book called The Stars: Steppingstones Into Space explains how astronomers find hidden in these patterns clues
orange yefJow
from which they figure out how hot a star is, how far away it is, and even how much it weighs. What interests us
here
is
the fact that these patterns also contain
another proof that the earth revolves around the sun.
The proof
based on the fact that the dark lines in many stars keep shifting their position in the spectrum, in a movement called the Doppler shift. Part of the time they shift toward the violet end, and then they shift back toward the red. They repeat the shifting in the same way every year. Let us see how this proves that the earth is revolving around the is
the spectra of
sun.
Light
is
a vibration that travels through space.
59
The
vibration in light of any color has a definite rhythm,
and the color depends on the rhythm. The vibrations are faster, for example, in violet light than they are in
red
light.
The rhythm
of the vibration
is
given by
its
number of vibrations that The vibrations travel to us through space in the form of waves. The frequency of the vibration in a ray of light is also the number of
frequency, which
tells
the
take place in a second.
waves that reach us
in a second. In a spectrum, the
colors are arranged according to their frequency.
The
low-frequency colors are near the red end of the spectrum, and the higher-frequency colors are near the violet. In the pattern of lines in a star's
spectrum, each
and this frequency can be measured. When the lines shift toward the violet end of the spectrum, it means that the frequency has increased. When they shift back toward the red end again, it means tliat the frequency has decreased. This change in the frequency is the clue that shows line represents a definite frequency,
that the earth
is
moving.
When
a ray of light of a par-
comes to us from a star, its waves are spaced out one behind the other, like lines of soldiers marching in a parade. If the earth were standing still with respect to the star, the waves would arrive at the earth with an unchanging frequency, a definite number coming in each second. But since the earth moves, this frequency keeps changing. When the earth moves toward the star, it is rushing toward the waves and therefore meets more of them in a second. The frequency of each line of light in the spectrum is increased, and so all the lines shift closer to the violet ticular color
60
end.
When
the earth moves
away from the
star, it is
running away from the approaching waves. This slows down the rate at which the waves reach the earth. The frequency of each Hue of Hght in the spectrum is decreased, and all the lines shift toward the red end of the spectrum.
The way
the lines in the spectra of the stars shift
back and forth shows that the earth is alternately approaching them and then moving away from them. As it moves around in its orbit, it is headed now toward one star, and now toward another, and so the shifting of the lines in the spectrum passes from one star to another. It is passed around in a circle, like a bean bag in a game, showing that the earth follows a curved
orbit rather than
moving
in a straight line.
that the shifting of the lines
way
after a year
is
is
repeated in
The fact the same
a sign that the earth completes a
round trip in its orbit in a year, and retraces over and over again.
The
its
steps
Parallax of Stars
The
light of the stars contains a third proof that the
earth revolves around the sun. This proof
based on the fact that when one object is viewed from several different positions, it is seen in a different direction each time. If you look at a tree that is directly in front of you, you look straight ahead to see
is
Then, if you move several yards to the left, you have to look to the right to see the tree. If you move to the right, then you have to look to the left to see the tree. In fact, as
you move past the
tree,
it.
because of your change in
61
position
it
looks as though the tree
is
moving the other
way. This apparent shift in the position of something you look at things
When
when you move you look
is
Not all the equally by parallax.
called parallax.
at are aflFected
you walk down a road past a group of trees, the trees seem to shift backward, but some of them shift more slowly than others. The nearest trees seem to shift the fastest, and the farther away a tree is, the more slowly it seems to move. The parallax of an object that you pass depends on how far away it is. Some of the nearer stars show a parallax shift that results from the motion of the earth in its orbit. The diagram on page 64 shows why this shift takes place. If the star shown in the diagram is observed in the 62
month
of January,
months If
later,
the star
is
tion, the star
it is
seen in a definite direction. Six
on the other side of the sun. observed now from the earth's new posithe earth
is
is
seen in a different direction.
in the earth's position as
•
it
moves along
The
its
shift
orbit
is
\;S^»i«