[Answer Question]
Before the Scientific Revolution, educated Europeans held a view of the world that derived from Aristotle, perhaps the greatest of the ancient Greek philosophers, and from Ptolemy, a Greco-Egyptian mathematician and astronomer who lived in Alexandria during the second century C.E. To medieval European thinkers, the earth was stationary and at the center of the universe, and around it revolved the sun, moon, and stars embedded in ten spheres of transparent crystal. This understanding coincided well with the religious outlook of the Catholic Church because the attention of the entire universe was centered on the earth and its human inhabitants, among whom God’s plan for salvation unfolded. It was a universe of divine purpose, with angels guiding the hierarchically arranged heavenly bodies along their way while God watched over the whole from his realm beyond the spheres. The Scientific Revolution was revolutionary because it fundamentally challenged this understanding of the universe.
The initial breakthrough in the Scientific Revolution came from the Polish mathematician and astronomer Nicolaus Copernicus, whose famous book On the Revolutions of the Heavenly Spheres was published in the year of his death, 1543. Its essential argument was that “at the middle of all things lies the sun” and that the earth, like the other planets, revolved around it. Thus the earth was no longer unique or at the obvious center of God’s attention.
Other European scientists built on Copernicus’s central insight, and some even argued that other inhabited worlds and other kinds of humans existed. Less speculatively, in the early seventeenth century Johannes Kepler, a German mathematician, showed that the planets followed elliptical orbits, undermining the ancient belief that they moved in perfect circles. The Italian Galileo (gal-uh-LAY-oh) developed an improved telescope, with which he observed sunspots, or blemishes, moving across the face of the sun. This called into question the traditional notion that no change or imperfection marred the heavenly bodies. His discovery of the moons of Jupiter and many new stars suggested a cosmos far larger than the finite universe of traditional astronomy. Some thinkers began to discuss the notion of an unlimited universe in which humankind occupied a mere speck of dust in an unimaginable vastness. The French mathematician and philosopher Blaise Pascal (1623–1662) perhaps spoke for many when he wrote: “The eternal silence of infinite space frightens me.”20
The culmination of the Scientific Revolution came in the work of Sir Isaac Newton, the Englishman who formulated the modern laws of motion and mechanics, which remained unchallenged until the twentieth century. At the core of Newton’s thinking was the concept of universal gravitation. “All bodies whatsoever,” Newton declared, “are endowed with a principle of mutual gravitation.”21 Here was the grand unifying idea of early modern science. The radical implication of this view was that the heavens and the earth, long regarded as separate and distinct spheres, were not so different after all, for the motion of a cannonball or the falling of an apple obeyed the same natural laws that governed the orbiting planets.
By the time Newton died, a revolutionary new understanding of the physical universe had emerged among educated Europeans. That universe was no longer propelled by supernatural forces but functioned on its own according to scientific principles that could be described mathematically. In Kepler’s view, “the machine of the universe is not similar to a divine animated being but similar to a clock.”22 Furthermore, it was a machine that regulated itself, requiring neither God nor angels to account for its normal operation. Knowledge of that universe could be obtained through human reason alone—by observation, deduction, and experimentation—without the aid of ancient authorities or divine revelation. The French philosopher René Descartes (day-KAHRT) resolved “to seek no other knowledge than that which I might find within myself, or perhaps in the book of nature.”23
Like the physical universe, the human body also lost some of its mystery. The careful dissections of cadavers and animals enabled doctors and scientists to describe the human body with much greater accuracy and to understand the circulation of the blood throughout the body. The heart was no longer the mysterious center of the body’s heat and the seat of its passions; instead it was just another machine, a complex muscle that functioned as a pump.
The movers and shakers of this enormous cultural transformation were almost entirely male. European women, after all, had been largely excluded from the universities where much of the new science was discussed. A few aristocratic women, however, had the leisure and connections to participate informally in the scientific networks of their male relatives. Through her marriage to the Duke of Newcastle, Margaret Cavendish (1623–1673) joined in conversations with a circle of “natural philosophers,” wrote six scientific texts, and was the only seventeenth-century English woman to attend a session of the Royal Society of London, created to foster scientific learning. In Germany, a number of women took part in astronomical work as assistants to their husbands or brothers. Maria Winkelman, for example, discovered a previously unknown comet, though her husband took credit for it. After his death, she sought to continue his work in the Berlin Academy of Sciences but was refused on the grounds that “mouths would gape” if a woman held such a position.
Much of this scientific thinking developed in the face of strenuous opposition from the Catholic Church, for both its teachings and its authority were under attack. The Italian philosopher Giordano Bruno, proclaiming an infinite universe and many worlds, was burned at the stake in 1600, and Galileo was compelled by the Church to publicly renounce his belief that the earth moved around an orbit and rotated on its axis.
But not all was conflict between the Church and an emerging science. None of the early scientists rejected Christianity. Galileo himself proclaimed the compatibility of science and faith when he wrote: “Nor is God any less excellently revealed in Nature’s actions than in the sacred statements of the Bible.”24 Newton was a serious biblical scholar and saw no necessary contradiction between his ideas and belief in God. “This most beautiful system of the sun, planets, and comets,” he declared, “could only proceed from the counsel and dominion of an intelligent Being.”25 The Church gradually accommodated as well as resisted the new ideas, largely by compartmentalizing them. Science might prevail in its limited sphere of describing the physical universe, but religion was still the arbiter of truth about those ultimate questions concerning human salvation, righteous behavior, and the larger purposes of life.
Thinker/Scientist Achievements | |
---|---|
Nicolaus Copernicus (Polish; 1473–1543) | Posited that sun is at the center of solar system, earth rotates on its axis, and earth and planets revolve around the sun |
Andreas Vesalius (Flemish; 1514–1564) | “Father of anatomy”; made detailed drawings of human body based on dissection |
Francis Bacon (English; 1561–1626) | Emphasized observation and experimentation as the key to modern science |
Galileo Galilei (Italian; 1564–1642) | Developed an improved telescope; discovered sunspots, mountains on the moon, and Jupiter’s moons; performed experimental work on the velocity of falling objects |
Johannes Kepler (German; 1571–1630) | Posited that planets follow elliptical, not circular, orbits; described laws of planetary motion |
William Harvey (English; 1578–1657) | Described the circulation of the blood and the function of the heart |
René Descartes (French; 1596–1650) | Emphasized the importance of mathematics and logical deduction in understanding the physical world; invented analytical geometry |
Isaac Newton (English; 1642–1727) | Synthesized earlier findings around the concept of universal gravitation; invented calculus; formulated concept of inertia and laws of motion |