Galileo Galilei, the great Italian scientist who was
probably more responsible for the development of the scientific method than any
other individual, was born in 1564, in the city of Pisa. As a young man, he
studied at the University of Pisa, but dropped
out for financial reasons. Nevertheless, he was able, in 1589, to obtain a teaching position at that university.
A few years later, he joined the faculty of the University of Padua and
remained there until 1610. It was during this period that the bulk of his
scientific discoveries were made.
Galileo's first important
contributions were made in mechanics.
Aristotle had taught that heavy objects fall at a more rapid rate than
light objects, and generations of scholars had accepted this assertion on the
Greek philosopher's authority. Galileo, however, decided to test it, and
through a series of experiments, he soon found that Aristotle had been incorrect. The fact is that heavy and light
objects fall at the same velocity except
performed these experiments by dropping objects from the Leaning Tower of Pisa seems to be without foundation.)Having learned this, Galileo took the next step. He carefully measured the distance that objects fall in a given period of time and found that the distance traversed by a falling object is proportional to the square of the number of seconds it has been falling. This discovery (which implies a uniform rate of acceleration) is significant in itself. Even more important, Galileo was able to summarize the results of a series of experiments by a mathematical formula. The extensive use of mathematical formulas and mathematical methods is an important characteristic of modern science.
performed these experiments by dropping objects from the Leaning Tower of Pisa seems to be without foundation.)Having learned this, Galileo took the next step. He carefully measured the distance that objects fall in a given period of time and found that the distance traversed by a falling object is proportional to the square of the number of seconds it has been falling. This discovery (which implies a uniform rate of acceleration) is significant in itself. Even more important, Galileo was able to summarize the results of a series of experiments by a mathematical formula. The extensive use of mathematical formulas and mathematical methods is an important characteristic of modern science.
Another of Galileo's major contributions was his
discovery of the law of inertia. Previously, people had believed that a moving object would naturally tend to slow down and stop unless some force were
exerted to keep it moving. But Galileo's experiments indicated that the common
belief was erroneous. If retarding forces, such as friction, could be
eliminated, a moving object would naturally tend to continue moving
indefinitely. This important principle, which Newton restated clearly and incorporated into his own system as the first law of motion, is one of the vital principles
of physics.
Illustration of Galilean law of leverage from Galileo's physics textbook Mathematical Discourses and Demonstrations.
Galileo's telescope.
Galileo's most celebrated discoveries were in
the field of astronomy. Astronomical theory
in the early 1600s was in a state of great ferment, with an important
dispute going on between the followers of the heliocentric theory of Copernicus
and the adherents of the earlier geocentric theory. As early as 1604, Galileo
had announced his belief that Copernicus was correct, but at that time he had
no method of proving it. In 1609, however, Galileo heard of the invention of
the telescope in Holland. Although he had only the barest description of the
device, Galileo's genius was such that he was soon able to construct a vastly
superior telescope himself. With this new tool, he turned his observational
talents to the heavens, and in a single year made a whole series of major
discoveries.
He looked at the moon and saw that it was not a
smooth sphere, but had numerous craters and high mountains on it. Celestial
objects, he concluded, were not smooth and perfect after all, but had the same sort of irregularities that one observed
on earth. He looked at the
Milky Way and saw that it was not a milky, nebulous body after all, but was composed of an enormous number of individual stars, which were so far away that the naked eye tended to blur them together. He looked at the planets and saw that four moons revolved around Jupiter. Here was clear evidence that an astronomical body could revolve about a planet other than Earth. He looked at the sun and observed sunspots. (Actually, other persons had observed sunspots before him, but Galileo publicized his observations more effectively and brought sunspots to the attention of the scientific world.) IIeobserved that the planet Venus had phases quite similar to the phases of the moon. This became a significant piece of evidence corroborating the Copernican theory that the earth and all the other planets revolve around the sun.
Milky Way and saw that it was not a milky, nebulous body after all, but was composed of an enormous number of individual stars, which were so far away that the naked eye tended to blur them together. He looked at the planets and saw that four moons revolved around Jupiter. Here was clear evidence that an astronomical body could revolve about a planet other than Earth. He looked at the sun and observed sunspots. (Actually, other persons had observed sunspots before him, but Galileo publicized his observations more effectively and brought sunspots to the attention of the scientific world.) IIeobserved that the planet Venus had phases quite similar to the phases of the moon. This became a significant piece of evidence corroborating the Copernican theory that the earth and all the other planets revolve around the sun.
The invention of
the telescope and the series of discoveries that resulted from it made Galileo
famous. However, by sup-porting the theory of Copernicus he aroused opposition
in important Church circles, and in 1616 he was ordered to refrain from
teaching the Copernican hypothesis. Galileo chafed under this restriction for
several years. When the Pope died, in 1623, he was succeeded by a man who had
been an admirer of Galileo. The following year the new Pope, Urban VIII, hinted
(though somewhat ambiguously) that the prohibition would no longer be in force.
Galileo spent
the next six years composing his most famous work, the Dialogue Concerning the Two Chief World Systems. This book was a masterly exposition
of the evidence in favor of the Copernican theory, and the book was published
in 1632 with the imprimatur of the Church censors.
Nevertheless, Church authorities responded in anger when the book appeared, and
Galileo was soon brought to trial before the Inquisition in Rome on charges of
having violated the 1616 prohibition.
It seems clear that
many churchmen were unhappy with the decision to prosecute the eminent scientist. Even
under the Church law of the time, the case against Galileo was questionable,
and he was given a comparatively light sentence. He was not, in fact, confined
to jail at all, but merely to house arrest in his own comfortable villa in
Arcetri. Theoretically, he was to have no visitors, but that provision of the
sentence was not enforced. His only other punishment was the requirement that
he publicly recant his view that the earth moved around the sun. This the sixty-nine-year-old scientist did in open
court. (There is a famous and probably apocryphal story that after he
finished making his retraction, Galileo looked down to the earth and whispered
softly, "It still moves.") In Arcetri he continued to write on
mechanics. He died there, in 1642.
Galileo's enormous contribution to
the advancement of science has long been
recognized. His importance rests in part on his scientific discoveries such as the law of inertia, his invention
of the telescope, his astronomical
observations, and his genius in proving the Copernican hypothesis. Of
greater importance,
The
Leaning Tower of Pisa, from which Galileo supposedly demonstrated the laws of falling bodies.
however, is his role in the development of the methodology of science. Most previous natural philosophers, taking their cues from Aristotle, had made qualitative observations and categorized phenomena; but Galileo measured phenomena and made quantitative observations. This emphasis on careful quantitative measurements has since become a basic feature of scientific research.
however, is his role in the development of the methodology of science. Most previous natural philosophers, taking their cues from Aristotle, had made qualitative observations and categorized phenomena; but Galileo measured phenomena and made quantitative observations. This emphasis on careful quantitative measurements has since become a basic feature of scientific research.
Galileo is
probably more responsible than any other man for
the empirical attitude of scientific research. It was he who first insisted
upon the necessity of performing experiments. He rejected the notion that scientific
questions could be decided by reliance upon authority, whether it be the
pronouncements of the Church or the
assertions of Aristotle. He also rejected reliance on complex deductive
schemes that were not based on a firm foundation
of experiment. Medieval scholastics had discussed at great length what should
happen and why things happen, but Galileo
insisted upon performing experiments to determine what actually did happen.
His scientific outlook was distinctly non-mystical;
in this respect, he was even more modern than some of his successors,
such as Newton.
Galileo, it might be noted, was a
deeply religious man. De-spite his trial and conviction, he did not reject
either religion or the church, but only the attempt of Church authorities to
stifle investigation of scientific matters. Later generations have quite rightly admired Galileo as a symbol of revolt
against dogmatism, and against authoritarian attempts to stifle freedom
of thought. Of greater importance, however, is the role he played in founding modern scientific method.
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