Nicolaus Copernicus - Astronomy, Heliocentrism, Revolution | Britannica (original) (raw)

Quick Facts

German:

Nikolaus Kopernikus

Died:

May 24, 1543, Frauenburg, East Prussia [now Frombork, Poland]

Also Known As:

Mikołaj Kopernik

Nikolaus Kopernikus

Nicolaus CopernicusEngraving from Christoph Hartknoch's book Alt- und neues Preussen (1684; “Old and New Prussia”), depicting Nicolaus Copernicus as a saintly and humble figure. The astronomer is shown between a crucifix and a celestial globe, symbols of his vocation and work. The Latin text below the astronomer is an ode to Christ's suffering by Pope Pius II: “Not grace the equal of Paul's do I ask / Nor Peter's pardon seek, but what / To a thief you granted on the wood of the cross / This I do earnestly pray.”

The contested state of planetary theory in the late 15th century and Pico’s attack on astrology’s foundations together constitute the principal historical considerations in constructing the background to Copernicus’s achievement. In Copernicus’s period, astrology and astronomy were considered subdivisions of a common subject called the “science of the stars,” whose main aim was to provide a description of the arrangement of the heavens as well as the theoretical tools and tables of motions that would permit accurate construction of horoscopes and annual prognostications. At this time the terms astrologer, astronomer, and mathematician were virtually interchangeable; they generally denoted anyone who studied the heavens using mathematical techniques. Pico claimed that astrology ought to be condemned because its practitioners were in disagreement about everything, from the divisions of the zodiac to the minutest observations to the order of the planets. A second long-standing disagreement, not mentioned by Pico, concerned the status of the planetary models. From antiquity, astronomical modeling was governed by the premise that the planets move with uniform angular motion on fixed radii at a constant distance from their centres of motion. Two types of models derived from this premise.

The first, represented by that of Aristotle, held that the planets are carried around the centre of the universe embedded in unchangeable, material, invisible spheres at fixed distances. Since all planets have the same centre of motion, the universe is made of nested, concentric spheres with no gaps between them. As a predictive model, this account was of limited value. Among other things, it had the distinct disadvantage that it could not account for variations in the apparent brightness of the planets since the distances from the centre were always the same.

A second tradition, deriving from Claudius Ptolemy, solved this problem by postulating three mechanisms: uniformly revolving, off-centre circles called eccentrics; epicycles, little circles whose centres moved uniformly on the circumference of circles of larger radius (deferents); and equants. The equant, however, broke with the main assumption of ancient astronomy because it separated the condition of uniform motion from that of constant distance from the centre. A planet viewed from the centre c of its orbit would appear to move sometimes faster, sometimes slower. As seen from Earth, removed a distance e from c, the planet would also appear to move nonuniformly. Only from the equant, an imaginary point at distance 2_e_ from Earth, would the planet appear to move uniformly. A planet-bearing sphere revolving around an equant point will wobble; situate one sphere within another, and the two will collide, disrupting the heavenly order. In the 13th century a group of Persian astronomers at Marāgheh discovered that, by combining two uniformly revolving epicycles to generate an oscillating point that would account for variations in distance, they could devise a model that produced the equalized motion without referring to an equant point.

The Marāgheh work was written in Arabic, which Copernicus did not read. However, he learned to do the Marāgheh “trick,” either independently or through a still-unknown intermediary link. This insight was the starting point for his attempt to resolve the conflict raised by wobbling physical spheres. Copernicus might have continued this work by considering each planet independently, as did Ptolemy in the Almagest, without any attempt to bring all the models together into a coordinated arrangement. However, he was also disturbed by Pico’s charge that astronomers could not agree on the actual order of the planets. The difficulty focused on the locations of Venus and Mercury. There was general agreement that the Moon and Sun encircled the motionless Earth and that Mars, Jupiter, and Saturn were situated beyond the Sun in that order. However, Ptolemy placed Venus closest to the Sun and Mercury to the Moon, while others claimed that Mercury and Venus were beyond the Sun.

In the Commentariolus, Copernicus postulated that, if the Sun is assumed to be at rest and if Earth is assumed to be in motion, then the remaining planets fall into an orderly relationship whereby their sidereal periods increase from the Sun as follows: Mercury (88 days), Venus (225 days), Earth (1 year), Mars (1.9 years), Jupiter (12 years), and Saturn (30 years). This theory did resolve the disagreement about the ordering of the planets but, in turn, raised new problems. To accept the theory’s premises, one had to abandon much of Aristotelian natural philosophy and develop a new explanation for why heavy bodies fall to a moving Earth. It was also necessary to explain how a transient body like Earth, filled with meteorological phenomena, pestilence, and wars, could be part of a perfect and imperishable heaven. In addition, Copernicus was working with many observations that he had inherited from antiquity and whose trustworthiness he could not verify. In constructing a theory for the precession of the equinoxes, for example, he was trying to build a model based upon very small, long-term effects. And his theory for Mercury was left with serious incoherencies.

Any of these considerations alone could account for Copernicus’s delay in publishing his work. (He remarked in the preface to De revolutionibus that he had chosen to withhold publication not for merely the nine years recommended by the Roman poet Horace but for 36 years, four times that period.) And, when a description of the main elements of the heliocentric hypothesis was first published, in the Narratio prima (1540 and 1541, “First Narration”), it was not under Copernicus’s own name but under that of the 25-year-old Georg Rheticus. Rheticus, a Lutheran from the University of Wittenberg, Germany, stayed with Copernicus at Frauenburg for about two and a half years, between 1539 and 1542. The Narratio prima was, in effect, a joint production of Copernicus and Rheticus, something of a “trial balloon” for the main work. It provided a summary of the theoretical principles contained in the manuscript of De revolutionibus, emphasized their value for computing new planetary tables, and presented Copernicus as following admiringly in the footsteps of Ptolemy even as he broke fundamentally with his ancient predecessor. It also provided what was missing from the Commentariolus: a basis for accepting the claims of the new theory.

Both Rheticus and Copernicus knew that they could not definitively rule out all possible alternatives to the heliocentric theory. But they could underline what Copernicus’s theory provided that others could not: a singular method for ordering the planets and for calculating the relative distances of the planets from the Sun. Rheticus compared this new universe to a well-tuned musical instrument and to the interlocking wheel-mechanisms of a clock. In the preface to De revolutionibus, Copernicus used an image from Horace’s Ars poetica (“Art of Poetry”). The theories of his predecessors, he wrote, were like a human figure in which the arms, legs, and head were put together in the form of a disorderly monster. His own representation of the universe, in contrast, was an orderly whole in which a displacement of any part would result in a disruption of the whole. In effect, a new criterion of scientific adequacy was advanced together with the new theory of the universe.