Galileo
Galileo (1564-1642), Italian physicist
and astronomer, who, with the German astronomer Johannes Kepler,
initiated the scientific revolution that flowered in the work of the English
physicist Sir Isaac Newton.
Born Galileo Galilei, his main contributions were, in
astronomy, the use of the telescope in observation and the discovery of
sunspots, lunar mountains and valleys, the four largest satellites of Jupiter,
and the phases of Venus. In physics, he discovered the laws of falling bodies
and the motions of projectiles. In the history of culture, Galileo stands as a
symbol of the battle against authority for freedom of inquiry.
Galileo was born near Pisa, on February 15, 1564. His father, Vincenzo Galilei, played an
important role in the musical revolution from medieval polyphony to harmonic
modulation. Just as Vincenzo saw that rigid theory
stifled new forms in music, so his eldest son came to see Aristotelian physical
theology as limiting scientific inquiry. Galileo was taught by monks at Vallombrosa and then entered the University of Pisa in 1581
to study medicine. He soon turned to philosophy and mathematics, leaving the
university without a degree in 1585. For a time he tutored privately and wrote
on hydrostatics and natural motions, but he did not publish. In 1589 he became
professor of mathematics at Pisa, where he is reported to have shown his
students the error of Aristotle’s belief that speed of fall is proportional to
weight, by dropping two objects of different weight simultaneously from the Leaning
Tower. His contract was not renewed in 1592, probably because he contradicted
Aristotelian professors. The same year, he was appointed to the chair of
mathematics at the University of Padua, where he remained until 1610.
At Padua, Galileo invented a calculating “compass” for the
practical solution of mathematical problems. He turned from speculative physics
to careful measurements, discovered the law of falling bodies and of the
parabolic path of projectiles, studied the motions of pendulums, and investigated
mechanics and the strength of materials. He showed little interest in
astronomy, although beginning in 1595 he preferred the Copernican theory (see
Astronomy: The Copernican Theory)—that the earth revolves around the
sun—to the Aristotelian and Ptolemaic assumption that planets circle a fixed
earth. Only the Copernican model supported Galileo’s tide theory, which was
based on motions of the earth. In 1609 he heard that a spyglass had been
invented in Holland. In August of that year he presented a telescope, about as
powerful as a modern field glass, to the doge of Venice. Its value for naval
and maritime operations resulted in the doubling of his salary and his
assurance of lifelong tenure as a professor.
By December 1609, Galileo had built a telescope of 20 times
magnification, with which he discovered mountains and craters on the moon. He
also saw that the Milky Way was composed of stars, and he discovered the four
largest satellites of Jupiter. He published these findings in March 1610 in The
Starry Messenger (trans. 1880). His new fame gained him appointment as
court mathematician at Florence; he was thereby freed from teaching duties and
had time for research and writing. By December 1610 he had observed the phases
of Venus, which contradicted Ptolemaic astronomy and confirmed his preference
for the Copernican system.
Professors of philosophy scorned Galileo’s discoveries because
Aristotle had held that only perfectly spherical bodies could exist in the
heavens and that nothing new could ever appear there. Galileo also disputed
with professors at Florence and Pisa over hydrostatics, and he published a book
on floating bodies in 1612. Four printed attacks on this book followed,
rejecting Galileo’s physics. In 1613 he published a work on sunspots and
predicted victory for the Copernican theory. A Pisan
professor, in Galileo’s absence, told the Medici (the ruling family of Florence
as well as Galileo’s employers) that belief in a moving earth was heretical. In
1614 a Florentine priest denounced Galileists from
the pulpit. Galileo wrote a long, open letter on the irrelevance of biblical
passages in scientific arguments, holding that interpretation of the Bible
should be adapted to increasing knowledge and that no scientific position
should ever be made an article of Roman Catholic faith.
Early in 1616, Copernican books were subjected to censorship by
edict, and the Jesuit cardinal Robert Bellarmine
instructed Galileo that he must no longer hold or defend the concept that the earth
moves. Cardinal Bellarmine had previously advised him
to treat this subject only hypothetically and for scientific purposes, without
taking Copernican concepts as literally true or attempting to reconcile them
with the Bible. Galileo remained silent on the subject for years, working on a
method of determining longitudes at sea by using his predictions of the
positions of Jupiter’s satellites, resuming his earlier studies of falling
bodies, and setting forth his views on scientific reasoning in a book on
comets, The Assayer (1623; trans. 1957).
In 1624 Galileo began a book he wished to call “Dialogue on the
Tides,” in which he discussed the Ptolemaic and Copernican hypotheses in
relation to the physics of tides. In 1630 the book was licensed for printing by
Roman Catholic censors at Rome, but they altered the title to Dialogue on
the Two Chief World Systems (trans. 1661). It was published at Florence in
1632. Despite two official licenses, Galileo was summoned to Rome by the
Inquisition to stand trial for “grave suspicion of heresy.” This charge was
grounded on a report that Galileo had been personally ordered in 1616 not to
discuss Copernicanism either orally or in writing.
Cardinal Bellarmine had died, but Galileo produced a
certificate signed by the cardinal, stating that Galileo had been subjected to
no further restriction than applied to any Roman Catholic under the 1616 edict.
No signed document contradicting this was ever found, but Galileo was
nevertheless compelled in 1633 to abjure and was sentenced to life imprisonment
(swiftly commuted to permanent house arrest). The Dialogue was ordered
to be burned, and the sentence against him was to be read publicly in every
university.
Galileo’s final book, Discourses Concerning Two New Sciences
(trans. 1662-65), which was published at Leiden in
1638, reviews and refines his earlier studies of motion and, in general, the
principles of mechanics. The book opened a road that was to lead Newton to the
law of universal gravitation that linked Kepler’s
planetary laws with Galileo’s mathematical physics. Galileo became blind before
it was published, and he died at Arcetri, near
Florence, on January 8, 1642.
Galileo’s most valuable scientific contribution was his founding
of physics on precise measurements rather than on metaphysical principles and
formal logic. More widely influential, however, were The Starry Messenger
and the Dialogue, which opened new vistas in astronomy. Galileo’s
lifelong struggle to free scientific inquiry from restriction by philosophical
and theological interference stands beyond science. Since the full publication
of Galileo’s trial documents in the 1870s, entire responsibility for Galileo’s
condemnation has customarily been placed on the Roman Catholic church. This conceals the role of the philosophy professors
who first persuaded theologians to link Galileo’s science with heresy. An
investigation into the astronomer’s condemnation, calling for its reversal, was
opened in 1979 by Pope John Paul II. In October 1992 a papal commission acknowledged
the Vatican’s error.
Microsoft ® Encarta ® Reference Library 2003.
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Galileo
b. Feb. 15, 1564,
Pisa [Italy]
d. Jan. 8, 1642, Arcetri,
near Florence
in full GALILEO GALILEI Italian natural philosopher,
astronomer, and mathematician who made fundamental contributions to the
sciences of motion, astronomy, and strength of materials and to the development
of the scientific method. His formulation of (circular) inertia, the law of
falling bodies, and parabolic trajectories marked the beginning of a
fundamental change in the study of motion. His insistence that the book of
nature was written in the language of mathematics changed natural philosophy
from a verbal, qualitative account to a mathematical one in which experimentation
became a recognized method for discovering the facts of nature. Finally, his
discoveries with the telescope
revolutionized astronomy and paved the way for the acceptance of the Copernican
heliocentric
system, but his advocacy of that system eventually resulted in an
Inquisition process against him.
Galileo was born
in Pisa, Tuscany, on Feb. 15, 1564, the oldest son of Vincenzo
Galilei ,
a musician who made important contributions to the theory and practice of music
and may have performed some experiments with Galileo in 1588-89 on the
relationship between pitch and the tension of strings. The family moved to
Florence in the early 1570s, where the Galilei family
had lived for generations. In his middle teens Galileo attended the monastery
school at Vallombrosa, near Florence, and then in
1581 matriculated at the University of Pisa, where he was to study medicine.
But he became enamoured with mathematics and decided to make the mathematical
subjects and philosophy his profession, against the protests of his father.
Galileo then began to prepare himself to teach Aristotelian
philosophy and mathematics, and several of his lectures have survived. In
1585 Galileo left the university without having obtained a degree, and for
several years he gave private lessons in the mathematical subjects in Florence
and Siena. During this period he designed a new form of hydrostatic
balance for weighing small quantities and wrote a short treatise, La bilancetta ("The Little Balance"), that circulated in manuscript form. He also began his
studies on motion, which he pursued steadily for the next two decades.
In 1588 he
applied for the chair of mathematics at the University of Bologna but was
unsuccessful. His reputation was, however, increasing, and later that year he
was asked to deliver two lectures to the Florentine Academy, a prestigious
literary group, on the arrangement of the world in Dante's Inferno. He
also found some ingenious theorems on centres of gravity (again, circulated in
manuscript) that brought him recognition among mathematicians and the patronage
of Guidobaldo del Monte
(1545-1607), a nobleman and author of several important works on mechanics.
As a result, he obtained the chair of mathematics at the University of Pisa in
1589. There, according to his first biographer, Vincenzo Viviani (1622-1703),
Galileo demonstrated, by dropping bodies of different weights from the top of
the famous, that the speed of fall of a heavy object is not proportional to its
weight, as Aristotle had claimed. The manuscript tract De motu (On Motion), finished
during this period, shows that Galileo was abandoning Aristotelian
notions about motion and was instead taking an Archimedean approach to the problem.
But his attacks on Aristotle made him unpopular with his colleagues, and in
1592 his contract was not renewed. His patrons, however, secured him the chair
of mathematics at the University of Padua, where he taught from 1592 until
1610.
Although Galileo's
salary was considerably higher there, his responsibilities as the head of the
family (his father had died in 1591) meant that he was chronically pressed for
money. His university salary could not cover all his expenses, and he therefore
took in well-to-do boarding students whom he tutored privately in such subjects
as fortification. He also sold a proportional compass, or sector, of his own
devising, made by an artisan whom he employed in his house. Perhaps because of
these financial problems, he did not marry, but he did have an arrangement with
a Venetian woman, Marina Gamba, who bore him two
daughters and a son. In the midst of his busy life he continued his research on
motion, and by 1609 he had determined that the distance fallen by a body is
proportional to the square of the elapsed time (the law of falling bodies) and
that the trajectory of a projectile is a parabola, both conclusions that
contradicted Aristotelian physics.
At this point,
however, his career took a dramatic turn. In the spring of 1609 Galileo heard
that in the Netherlands an instrument had been invented that showed distant
things as though they were nearby. By trial and error, he quickly figured out
the secret of the invention and made his own three-powered spyglass from lenses
for sale in spectacle makers' shops. Others had done the same; what set Galileo
apart was that he quickly figured out how to improve the instrument, taught
himself the art of lens grinding, and produced increasingly powerful
telescopes. In August of that year he presented an eight-powered instrument to
the Venetian Senate (Padua was in the Venetian Republic).
Two of Galileo's first telescopes. In the Museum of Science, Florence, Italy.
He was rewarded with life tenure and a doubling of his salary.
Galileo was now one of the highest-paid professors at the university. In the
fall of 1609 Galileo began observing the heavens with instruments that magnified
up to 20 times. In December he drew the Moon's
phases as seen through the telescope, showing that the Moon's surface is not
smooth, as had been thought, but is rough and uneven.
Galileo's sepia wash studies of the Moon, 1609. In the Biblioteca Nazionale,
Florence, Italy.
In January 1610 he discovered four moons revolving around Jupiter.
He also found that the telescope showed many more stars than are visible with
the naked eye. These discoveries were earthshaking, and Galileo quickly
produced a little book, Sidereus Nuncius (The
Sidereal Messenger), in which he described them.
Galileo's illustrations of the Moon from his Sidereus
Nuncius (1610; The Sidereal...
He dedicated the book to Cosimo II de Medici (1590-1621), the grand duke of his
native Tuscany, whom he had tutored in mathematics for several summers, and he
named the moons of Jupiter after the Medici family: the Sidera
Medicea, or "Medicean
Stars." Galileo was rewarded with an appointment as mathematician and
philosopher of the grand duke of Tuscany, and in the fall of 1610 he returned
in triumph to his native land.
Galileo was now a
courtier and lived the life of a gentleman. Before he left Padua he had
discovered the puzzling appearance of Saturn,
later to be shown as caused by a ring surrounding it, and in Florence he
discovered that Venus
goes through phases just as the Moon does. Although these discoveries did not
prove that the Earth was a planet orbiting the Sun, they undermined
Aristotelian cosmology: the absolute difference between the corrupt earthly
region and the perfect and unchanging heavens was proved wrong by the
mountainous surface of the Moon, the moons of Jupiter showed that there had to
be more than one centre of motion in the universe, and the phases of Venus
showed that it (and, by implication, Mercury) revolved around the Sun. As a
result, Galileo was confirmed in his belief, which he had probably held for
decades but which had not been central to his studies, that the Sun
was the centre of the universe and that the Earth is a planet, as Copernicus
had argued. Galileo's conversion to Copernicanism
would be a key turning point in the scientific
revolution.
After a brief
controversy about floating bodies, Galileo again turned his attention to the
heavens and entered a debate with Christoph Scheiner
(1573-1650), a German Jesuit and professor of mathematics at Ingolstadt, about the nature of sunspots
(of which Galileo was an independent discoverer). This controversy resulted in
Galileo's Istoria e dimostrazioni
intorno alle macchie solari e loro accidenti ("History
and Demonstrations Concerning Sunspots and Their Properties," or
"Letters on Sunspots"), which appeared in 1613. Against Scheiner, who, in an effort to save the perfection of the
Sun, argued that sunspots were satellites of the Sun, Galileo argued that the
spots are on or near the Sun's surface, and he bolstered his argument with a
series of detailed engravings of his observations.
Galileo's Copernicanism
Galileo's increasingly
overt Copernicanism began to cause trouble for him.
In 1613 he wrote a letter to his student Benedetto Castelli (1528-1643) in Pisa about the problem of squaring
the Copernican theory with certain biblical passages. Inaccurate copies of this
letter were sent by Galileo's enemies to the Inquisition
in Rome, and he had to retrieve the letter and send an accurate copy. Several
Dominican fathers in Florence lodged complaints against Galileo in Rome, and
Galileo went to Rome to defend the Copernican cause and his good name. Before
leaving, he finished an expanded version of the letter to Castelli,
now addressed to the grand duke's mother and good friend of Galileo, the
dowager Christina. In his Letter to the Grand Duchess Christina, Galileo
discussed the problem of interpreting biblical passages with regard to
scientific discoveries but, except for one example, did not actually interpret
the Bible. That task had been reserved for approved theologians in the wake of
the Council
of Trent (1545-63) and the beginning of the Catholic
Counter-Reformation.
But the tide in Rome was turning against the Copernican theory, and in 1615,
when the cleric Paolo Antonio Foscarini (c.
1565-1616) published a book arguing that the Copernican theory did not conflict
with scripture, Inquisition consultants examined the question and pronounced
the Copernican theory heretical. Foscarini's book was
banned, as were some more technical and nontheological
works, such as Johannes Kepler's Epitome of
Copernican Astronomy. Copernicus' own 1543 book, De revolutionibus
orbium coelestium libri VI ("Six Books Concerning the Revolutions of
the Heavenly Orbs"), was suspended until corrected. Galileo was not
mentioned directly in the decree, but he was admonished by (1542-1621) not to
"hold or defend" the Copernican theory. An improperly prepared
document placed in the Inquisition files at this time states that Galileo was
admonished "not to hold, teach, or defend" the Copernican theory
"in any way whatever, either orally or in writing."
Galileo was thus
effectively muzzled on the Copernican issue. Only slowly did he recover from
this setback. Through a student, he entered a controversy about the nature of
comets occasioned by the appearance of three comets in 1618. After several
exchanges, mainly with Orazio Grassi
(1583-1654), a professor of mathematics at the Collegio
Romano, he finally entered the argument under his own name. Il
saggiatore (The Assayer), published in 1623, was
a brilliant polemic on physical reality and an exposition of the new scientific
method. Galileo here discussed the method of the newly emerging science,
arguing:
Philosophy is
written in this grand book, the universe, which stands continually open to our
gaze. But the book cannot be understood unless one first learns to comprehend
the language and read the letters in which it is composed. It is written in the
language of mathematics, and its characters are triangles, circles, and other
geometric figures without which it is humanly impossible to understand a single
word of it.
He also drew a
distinction between the properties of external objects and the sensations they
cause in us--i.e., the distinction between primary and secondary qualities.
Publication of Il saggiatore
came at an auspicious moment, for Maffeo Cardinal Barberini (1568-1644), a friend, admirer, and patron of
Galileo for a decade, was named Pope as the book was going to press. Galileo's
friends quickly arranged to have it dedicated to the new pope. In 1624 Galileo
went to Rome and had six interviews with Urban VIII. Galileo told the pope
about his theory of the tides (developed earlier), which he put forward as
proof of the annual and diurnal motions of the Earth. The pope gave Galileo
permission to write a book about theories of the universe but warned him to
treat the Copernican theory only hypothetically. The book, Dialogo sopra i
due massimi sistemi del mondo, tolemaico
e copernicano (Dialogue Concerning the Two
Chief World Systems, Ptolemaic & Copernican), was finished in 1630, and
Galileo sent it to the Roman censor.
Copernicus. Ptolemy holds an astrolabe, Copernicus a model of a
planet orbiting the Sun.
Because of an outbreak of the plague, communications between
Florence and Rome were interrupted, and Galileo asked for the censoring to be
done instead in Florence. The Roman censor had a number of serious criticisms
of the book and forwarded these to his colleagues in Florence. After writing a
preface in which he professed that what followed was written hypothetically,
Galileo had little trouble getting the book through the Florentine censors, and
it appeared in Florence in 1632.
In the Dialogue's
witty conversation between Salviati (representing
Galileo), Sagredo (the intelligent layman), and Simplicio (the dyed-in-the-wool Aristotelian), Galileo gathered
together all the arguments (mostly based on his own telescopic discoveries) for
the Copernican theory and against the traditional geocentric cosmology. As
opposed to Aristotle's, Galileo's approach to cosmology is fundamentally
spatial and geometric: the Earth's axis retains its orientation in space as the
Earth circles the Sun, and bodies not under a force retain their velocity
(although this inertia is ultimately circular). But in giving Simplicio the final word, that God could have made the
universe any way he wanted to and still made it appear to us the way it does,
he put Pope Urban VIII's favourite argument in the
mouth of the person who had been ridiculed throughout the dialogue. The
reaction against the book was swift. The pope convened a special commission to
examine the book and make recommendations; the commission found that Galileo
had not really treated the Copernican theory hypothetically and recommended
that a case be brought against him by the Inquisition.
Galileo was summoned to Rome in 1633. During his first appearance before the
Inquisition, he was confronted with the 1616 edict recording that he was
forbidden to discuss the Copernican theory. In his defense
Galileo produced a letter from Cardinal Bellarmine,
by then dead, stating that he was admonished only not to hold or defend the
theory. The case was at somewhat of an impasse, and, in what can only be called
a plea bargain, Galileo confessed to having overstated his case. He was
pronounced to be vehemently suspect of heresy and was condemned to life
imprisonment and was made to abjure formally. There is no evidence that at this
time he whispered, "Eppur si
muove" ("And yet it moves"). It should
be noted that Galileo was never in a dungeon or tortured; during the
Inquisition process he stayed mostly at the house of the Tuscan ambassador to
the Vatican and for a short time in a comfortable apartment in the Inquisition
building. After the process he spent six months at the palace of Ascanio Piccolomini (c.
1590-1671), the archbishop of Siena and a friend and patron, and then moved
into a villa near Arcetri, in the hills above
Florence. He spent the rest of his life there. Galileo's daughter Sister Maria Celeste,
who was in a nearby nunnery, was a great comfort to her father until her
untimely death in 1634.
Galileo was then
70 years old. Yet he kept working. In Siena he had begun a new book on the
sciences of motion and strength of materials. There he wrote up his unpublished
studies that had been interrupted by his interest in the telescope in 1609 and
pursued intermittently since. The book was spirited out of Italy and published
in Leiden, Neth., in 1638
under the title Discorsi e dimostrazioni matematiche intorno a due nuove scienze attenenti
alla meccanica
(Dialogues Concerning Two New Sciences). Galileo here treated for the first
time the bending and breaking of beams and summarized his mathematical and
experimental investigations of motion, including the law of falling bodies and
the parabolic path of projectiles as a result of the mixing of two motions,
constant speed and uniform acceleration. By then Galileo had become blind, and
he spent his time working with a young student, Vincenzo
Viviani, who was with him when he died on Jan. 8,
1642.