Galileo Article
Galileo’s Achievements
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Galileo (1564–1642), Italian natural philosopher, mathematician, and astronomer, devised new scientific ways to investigate the mysteries of nature. His methods were based on mathematics and geometry and not on philosophical theories. Throughout his long career, Galileo revolutionized many fields in science, particularly the studies of motion, astronomy, and materials. His emphasis on direct observation and experimentation helped develop the scientific method. Galileo strongly supported the Copernican heliocentric theory. This brought him into conflict with the Roman Catholic Inquisition.
Early Genius
Galileo’s father had expected him to study medicine when Galileo entered the University of Pisa in 1581. Instead, Galileo became fascinated with mathematics and decided on a career in mathematical subjects and philosophy. He left the university without obtaining a degree. Yet Galileo showed his early genius by designing a new form of hydrostatic balance to measure small quantities. His short treatise “The Little Balance,” combined with his initial studies of motion, earned him recognition among mathematicians. In 1589 Galileo obtained the chair of mathematics at the University of Pisa, where he pursued his studies of motion.
Studies of Objects in Motion
Galileo used direct observation, experimentation, and mathematics to show that many of Aristotle’s ideas on motion, which had endured more than 1,900 years, were incorrect. In one of his most famous experiments, Galileo dropped objects of different weights off the Leaning Tower of Pisa. He found that the speed of fall of a heavy object is not proportionate to its weight, as Aristotle had claimed. His attacks on Aristotle made him unpopular with his colleagues in Pisa. In 1592 Galileo’s patrons secured a position for him at the University of Padua, where he taught until 1610. During this time he determined the law of falling bodies and calculated the curved trajectory, or parabola, of a projectile. Both conclusions contradicted Aristotle’s physics.
Astronomical Studies
In the spring of 1609 Galileo’s career took a dramatic turn toward astronomy. He had learned about the telescope, invented in the Netherlands, and developed his own increasingly powerful instruments. When he turned his telescopes to the heavens, he made several startling discoveries. Galileo found that the Moon’s surface was rough and uneven, not smooth as had been thought. His telescope also detected far more stars than were visible with the naked eye. In January 1610 he observed four moons orbiting around Jupiter and later discovered that Venus went through phases just as the Moon does. He also observed spots on the Sun’s “perfect” surface. These astronomical discoveries confirmed Galileo’s belief that Polish astronomer Nicolaus Copernicus had been correct when he formulated a solar system centered on the Sun, with Earth and other planets moving around it. Galileo summarized his observations in his book The Sidereal Messenger.
Galileo, Copernicus, and the Inquisition
Galileo’s increasing support of the Copernican theory began to cause him trouble with the Roman Catholic Church. In his Letter to the Grand Duchess Christina, Galileo discusses the problem of reconciling Copernican theory with passages in the Bible. However, the tide in Rome had turned against this theory; in 1615 the Inquisition declared it heretical. Galileo was admonished not to “hold, teach, or defend” the Copernican theory “in any way whatever, either orally or in writing.” Galileo did not entirely abandon the topic but approached it from another perspective. In 1623 he published a brilliant discussion on the nature of physical reality and a description of the new scientific method. Galileo argued that the “grand book, the universe” was written in the language of mathematics and geometry. This changed natural philosophy from a verbal account to a mathematical one in which experimentation became a recognized method for discovering the facts of nature. The next year Galileo received permission from Pope Urban VIII to write a book about theories of the universe. The result was Dialogue Concerning the Two Chief World Systems, Ptolemaic & Copernican, published in 1632. The book is a witty discussion among three characters: Salviati (Galileo); Sagredo, an intelligent layman; and Simplicio, a devout Aristotelian who is a figure of ridicule. In the book Galileo summarizes the arguments for the Copernican theory, based on his astronomical observations. Aristotle’s views are put in the mouth of the simpleton in the dialogue. The Vatican’s reaction to the book was swift. In 1633 the Inquisition leveled a charge of heresy against Galileo and sentenced him to life imprisonment. Friends and patrons intervened, and he spent the rest of his life under house arrest in a villa near Arcetri, close to Florence. Galileo’s final book, Dialogues Concerning Two New Sciences, summarized his studies on motion and his work on testing the strength of different materials. The manuscript was smuggled out of Italy and published in the Netherlands in 1638. On January 8, 1642, Galileo died, at the age of 77.
Legacy of Galileo
Galileo has been called “the father of modern science.” Because of his work, experimentation and observation became a recognized scientific method for investigating the facts and laws of nature. He instituted fundamental changes in the study of motion, astronomy, cosmology, physics, biology, and material science. Galileo’s inventions, from balances to telescopes and microscopes, brought him widespread recognition. In 1992 Pope John Paul II officially declared, before the Pontifical Academy of Sciences in Rome, that Galileo had been right to support Copernicus.
Galileo (Galilei) summary
Galileo (Galilei) summary
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planet Summary
Planet, (from Greek planētes, “wanderers”), broadly, any relatively large natural body that revolves in an orbit around the Sun or around some other star and that is not radiating energy from internal nuclear fusion reactions. In addition to the above description, some scientists impose additional
solar system Summary
Solar system, assemblage consisting of the Sun—an average star in the Milky Way Galaxy—and those bodies orbiting around it: 8 (formerly 9) planets with more than 210 known planetary satellites (moons); many asteroids, some with their own satellites; comets and other icy bodies; and vast reaches of