Gravity if one of the four fundamental forces in the universe. Though the fundamental
principles of it eluded scientists until Sir Isaac Newton was able to mathematically
describe it in 1687 (Eddington 93). Gravity plays a serious part in everyday actions as
it keeps everything on the ground; without gravity everything would be immobile unless a
force was applied (then it would move infinitely because there would be no force to stop
it).
Perhaps, the best place to start then would be with such a simple item as an apple
(after all it is what "sparked" Newton's creativity). The apple is one of the two
curiosities (the other being the moon) that led Newton to discover The Law of Universal
Gravitation in 1666 (Eddington 93). As Newton later wrote, it is the story of the sight
of an apple falling to the ground (he was resting at Woolsthorpe because of the plague at
Cambridge) that caused Newton to wonder if this same force was what held the moon in
place (Gamow 41).
Newton knew that an object fell to the earth at a rate of about 9.8 meters (32 feet) per
second second as pointed out by Galileo. Thus "the apple that fell from the tree" fell
to Earth at about this rate. For the first basic explanation of this we will assume a
linear plane, one in which all forces act in only one direction. Therefore when the
apple fell it went straight towards the center of the earth (accelerating at about 9.8
meters per second second). Newton then figured that the same force that pulled the apple
to Earth also pulls the moon to the earth. But what force keeps the moon from flying
into the earth or the earth flying into the sun (Edwards 493)?
To better understand this, one other aspect must first be understood. Galileo showed
that all objects fall to the earth at the same rate (the classic cannonball and feather
proved this). But why? If a piano and a saxophone were both dropped from the top of the
Empire State Building then they would both slam into the ground at the same rate. Newton
realized then that the moon and the apple were both being pulled towards Earth at the
same rate but yet the moon was the only one who resisted the force and stayed in its
elliptical orbit (Eddington 94).
Newton's Third Law of Motion says that every force exerted by one object on another is
equal to a force, but opposite in direction, exerted be the second object on the first
(every reaction has an equal but opposite reaction). So the force of the earth pulling
the apple to the ground is proportionally the same as the force the apple exerts back on
the earth.
Now Johannes Kepler lived some forty-five years before Isaac Newton. And he showed that
the orbits of the planets in our solar system were elliptical. When the time of Newton
came around he mathematically proved that, if Kepler's First Law was true, then the force
on a planet varied inversely with the square of the distance between the planet and the
sun. He did this using Kepler's Third Law (Zitzewitz 160). The distance in this formula
is from the center of the masses and is the average distance over their entire period.
It is also important to note that the force acted in the direction of this line (an
important factor when dealing with vectors) (Zitzewitz 160).
Figure 1
Newton, confident that his idea of all objects exerting a force back on Earth, devised a
formula for Universal Gravitation. It is important to note that Newton was not the first
to think of Universal Gravitation, he was just the first one to make considerable and
remarkable proofs for it based on mathematical explanations. He said that if force is
relative to the mass of an object and it's acceleration then the force between two
objects must also be the same. Thus he came up with the first part of the equation.
Also, as he had proved earlier using Kepler's Third Law of Motion, that the force between
two objects is inversely proportional to their distances squared (an inverse square law),
then that must also be part of the Universal Gravitation equation. Thus we know that the
two masses and the distance are related to the force; and because the distance is
inversely proportional then the product of the masses divided by the distance between
their centers squared must equal the force between the two objects (Zitzewitz 161).
Now earlier, Newton had proved that the force on an object was proportional to an
object's mass and its acceleration. And the equation that he had formulated so far did
not include anything that would resemble the acceleration. Thus he knew that a
gravitational constant must be present and that it should be the same throughout all of
the universe. However, due to scientific limitations he was never able to figure out the
exact value of this constant (Zitzewitz 161).
Figure 2
One hundred years later, though, an young engineer by the name of Cavendish devised a
complex apparatus that was able to measure this gravitational constant. Basically by
using very sensitive telescopes and known angles he was able to determine the distance
one ball moved another ball. This is often known as "weighing the earth" (Zitzewitz
162-163).
The effects of Newton's Law of Universal Gravitation were varied; but the most common
use for his law was the prediction of several planets beyond Jupiter and Saturn. In
1830, it appeared that Newton's Law of Universal Gravitation had not been correct because
the orbit of Saturn did not follow his law. Some astronomers thought that the force of
an undiscovered planet may be changing its course and in 1845 a couple of scientists at
the Berlin Observatory began searching for this hidden planet. It did not take very
long. The massive planet now known as Neptune was found on the first night of searching
(Zitzewitz 164).
Perhaps one of the most key things about any theory of gravity prior to Einstein was the
fact that none of them proposed the origin of gravity. Newton's law always proved to be
true in the common world but did not explain the source of the force (Eddington 95).
Albert Einstein proposed his Theory of Gravity in his General Theory of Relativity. In
this he said that space was a three dimensional plane and that masses curved this plane
in one way or another (Eddington 95). Thus a massive object would cause a large "hole"
and smaller objects would "orbit" it. It is interesting to note that in either case,
Newton's or Einstein's law, both prove to be true in the common world. Massive universal
objects, such as black holes, are an exception but that's another story in itself
(Edwards 498).
Works Cited
Zitzewitz, Paul W., Robert F. Neff, and Mark Davids. (1992). Physics: Principles and
Problems.
Peoria, Illinois: Glencoe.
Gamow, George. (1962). Gravity: Classic and Modern Views. Garden City, New York:
Anchor Books.
Eddington, Sir Arthur. (1987). Space, Time, & Gravitation: An Outline of the General
Relativity Theory. Cambridge: Cambridge University Press.
Edwards, Paul. (Ed.) (1967). The Encyclopedia of Philosophy. New York, New York:
MacMillan.
|