A More Perfect Heaven
Page 1
A More PERFECT HEAVEN
How Copernicus Revolutionized the Cosmos
DAVA SOBEL
Contents
Cover
Title Page
Decdication
“To the Reader, Concerning … This Work”
Part One • Prelude
Chapter 1
Moral, Rustic, and Amorous Epistles
Chapter 2
The Brief Sketch
Chapter 3
Leases of Abandoned Farmsteads
Chapter 4
On the Method of Minting Money
Chapter 5
The Letter Against Werner
Chapter 6
The Bread Tariff
Part Two • Interplay
“And the Sun Stood Still”. ACT I
“And the Sun Stood Still”. ACT II
Part Three • Aftermath
Chapter 7
The First Account
Chapter 8
On the Revolutions of the Heavenly Spheres
Chapter 9
The Basel Edition
Chapter 10
Epitome of Copernican Astronomy
Chapter 11
Dialogue Concerning the Two Chief Systems of the World, Ptolemaic and Copernican
Chapter 12
An Annotated Census of Copernicus’ De Revolutionibus
Thanksgiving
Copernican Chronology
Notes on the Quotations
Illustration Credits
Maps
Bibliography
Footnotes
A Note on the Author
Also by Dava Sobel
Imprint
To my fair nieces,
AMANDA SOBEL
and
CHIARA PEACOCK,
with love in the Copernican
tradition of nepotism.
“To the Reader, Concerning
… This Work”
Since 1973, when the five hundredth anniversary of his birth brought his unique story to my attention, I have wanted to dramatize the unlikely meeting between Nicolaus Copernicus and the uninvited visitor who convinced him to publish his crazy idea.
Around the year 1510, near the age of forty, Copernicus reenvisioned the cosmos with the Sun, rather than the Earth, at its hub. Then he concealed the theory for thirty years, fearful of ridicule from his mathematician peers. But when his unexpected guest, called Rheticus, made the dangerous, several-hundred-mile journey to northern Poland in 1539, eager to learn the novel planetary order from its source, the aging Copernicus agreed to end his silence. The youth stayed on for two years, despite laws barring his presence, as a Lutheran, from Copernicus’s Catholic diocese during this contentious phase of the Protestant Reformation. Rheticus helped his mentor prepare the long-neglected manuscript for publication, and later hand-carried it to Nuremberg, to the best printer of scientific texts in Europe.
No one knows what Rheticus said to change Copernicus’s mind about going public. Their dialogue in the two-act play that begins on page 81 is my invention, although the characters occasionally speak the very words they wrote themselves in various letters and treatises. I had intended the play to stand on its own, but I thank my perceptive editor, George Gibson, for urging me to plant it in the broad context of history by surrounding the imagined scenes with a fully documented factual narrative that tells Copernicus’s life story and traces the impact of his seminal book, On the Revolutions of the Heavenly Spheres, to the present day.
Part One
Prelude
Bless the Lord, O my soul.
Who layeth the beams of his chambers in the waters: who maketh the clouds his chariot: who walketh upon the wings of the wind.
Who laid the foundations of the Earth, that it should not be removed for ever.
—PSALM 104:1, 3, 5
The great merit of Copernicus, and the basis of his claim to the discovery in question, is that he was not satisfied with a mere statement of his views, but devoted a large part of the labor of a life to their demonstration, and thus placed them in such a light as to render their ultimate acceptance inevitable.
—FROM Popular Astronomy (1878),
BY SIMON NEWCOMB, FOUNDING PRESIDENT OF
THE AMERICAN ASTRONOMICAL SOCIETY
Chapter 1
Moral, Rustic, and Amorous Epistles
The cricket is a musical being. At the break of dawn it starts to sing. But much louder and more vociferous, according to its nature, is it heard at the noon hour, because intoxicated by the Sun’s rays. As the songster chirps, then, it turns the tree into a platform and the field into a theater, performing a concert for the wayfarers.
—FROM Letters of Theophylactus Simocatta,
THE FIRST PUBLISHED WORK BY COPERNICUS, 1509
Nicolaus Copernicus, the man credited with turning our perception of the cosmos inside out, was born in the city of Torun, part of “Old Prussia” in the Kingdom of Poland, at 4:48 on Friday afternoon, the nineteenth of February, 1473. His horoscope for that auspicious moment (preserved in the Bavarian State Library in Munich) shows the Sun at 11° of Pisces in the sixth house, while Jupiter and the Moon are “conjunct,” or practically on top of one another, at 4° and 5°, respectively, of Sagittarius, in the third house. Whatever clues to character or destiny such data may contain, this particular natal chart is an after-the-fact construct, created at the end of the astronomer’s life and not the beginning of it (with the time of birth calculated, as opposed to copied from a birth certificate). At the time his horoscope was cast, Copernicus’s contemporaries already knew he had fathered an alternate universe—that he had defied common sense and received wisdom to place the Sun at the center of the heavens, then set the Earth in motion around it.
Nearing seventy, Copernicus had little cause to recall the exact date of his birth, let alone the hour of it down to the precision of minutes. Nor had he ever expressed the slightest faith in any astrological prognostications. His companion at the time, however, a professed devotee of the “juridical art,” apparently pressed Copernicus for biographical details to see how his stars aligned.
The horoscope’s symbols and triangular compartments position the Sun, Moon, and planets above or below the horizon, along the zodiac—the ring of constellations through which they appear to wander. The numerical notations describe more precisely where they lie at the moment, with respect to the twelve signs and also twelve so-called houses governing realms of life experience. Although the diagram invites interpretation, no accompanying conjecture has survived alongside it. One modern astrologer, invited to consider Copernicus’s case, used computer software to draw a new configuration in the shape of a wheel, and added solar-system bodies unknown in his time. Uranus and Neptune thus crept into the third house beside the Moon and Jupiter, while Pluto, a dark force, manifested itself opposite the Sun, at 16° of Virgo in the first house. The Pluto-Sun opposition drew a gasp from the astrologer, who declared it the hallmark of a born revolutionary.
The bold plan for astronomical reform that Copernicus conceived and then nurtured over decades in his spare time struck him as the blueprint for the “marvelous symmetry of the universe.” Even so, he proceeded cautiously, first leaking the idea to a few fellow mathematicians, never trying to proselytize. All the while real and bloody revolutions—the Protestant Reformation, the Peasant Rebellion, warfare with the Teutonic Knights and the Ottoman Turks—churned around him. He held off publishing his theory for so long that when his great book, On the Revolutions of the Heavenly Spheres, finally appeared in print, its author breathed his last. He never heard any of the criticism, or acclaim, that attended On the Revolutions. Decades after his death, when the first telescopic discoveries lent credence
to his intuitions, the Holy Office of the Inquisition condemned his efforts. In 1616, On the Revolutions was listed on the Index of Prohibited Books, where it remained for more than two hundred years. The philosophical conflict and change in perception that his ideas engendered are sometimes referred to as the Copernican Revolution.
HOROSCOPE FOR NICOLAUS COPERNICUS
Astronomers and astrologers in Copernicus’s time shared the same pool of information about the positions of the heavenly bodies against the backdrop of the stars. Until the invention of the telescope in the seventeenth century, position finding and position predicting constituted the entirety of planetary science—and the basis for casting horoscopes.
He was christened for his father—Mikolaj in Polish, Niklas in German, his native tongue. Later, as a scholar, he Latinized his name, but he grew up Niklas Koppernigk, the second son and youngest child of a merchant family from the copper-mining regions of Silesia. Their ancestral village of Koperniki could have taken its name from the Slavic word for the dill plant, koper, or from the Old German term for the metal mined there, kopper—or maybe it commemorated both those products of its hillsides. In any case, the roots of Koperniki’s etymology lay long buried by the time its younger generations began leaving home to seek new fortunes in the towns and cities. An armorer named Mikolaj Kopernik appeared in the city chronicles of Krakow in 1375, followed by mention of the mason Niclos Kopernik in 1396 and the rope maker Mikolaj Kopernik in 1439, all bearing the names of their forefathers’ homeland and its popular patron saint.
Around the year 1456, the alderman Mikolaj Koppernigk, who traded in Hungarian copper, moved north from Krakow to Torun, where he married Barbara Watzenrode. They lived on narrow St. Anne’s Lane, later renamed Copernicus Street, and raised four children in a tall brick house that is now a museum to the memory of their famous son. From the double front doors under the house’s pointed arch, their two boys, Andrei and Niklas, could walk to classes at the parish school of St. John’s Church, or down to the family warehouse near the wide river, the Vistula, that coursed from Krakow past Warsaw through Torun, carrying the flow of commerce to Danzig on the Baltic Sea.
Soon after the boy Niklas reached ten years of age, the elder Niklas died. His bereft sons and daughters and his widow, Barbara Koppernigk, turned for succor to her brother, Lukasz Watzenrode, a minor cleric, or “canon,” in a nearby diocese. Or perhaps Barbara, whose date of death is not recorded, had predeceased her husband, leaving her brood true orphans. Either way, the children came under their uncle’s care. Canon Watzenrode arranged a marriage contract for his niece Katyryna with Bartel Gertner of Krakow and consigned his niece Barbara to the Cistercian convent at Kulm. His young nephews he supported at school, first in Torun and later in Kulm or Wloclawek, until they were ready to attend his alma mater, the Jagiellonian University in Krakow. By then Uncle Lukasz had risen from a mediocre position in the Catholic hierarchy to become Bishop of Varmia.
A page of Gothic script in the archives of the Collegium Maius at the Jagiellonian University attests that Nicolaus Copernicus, age eighteen, paid his tuition fees in full for the fall of 1491. He studied logic, poetry, rhetoric, natural philosophy, and mathematical astronomy. According to the courses in his curriculum, his father’s copper and other common substances could not be considered elements in the modern sense of the periodic table. Rather, they comprised some combination of the four classic elements: earth, water, air, and fire. The heavens, in contrast, consisted entirely of a fifth essence, called ether, which differed from the other four by virtue of being inviolate and everlasting. Ordinary objects on Earth moved more or less along straight paths, whether seeking their natural places in the world order or being compelled by outside agents. Heavenly bodies, however, lay cocooned in celestial spheres that spun in eternal perfect circles.
The motions of the planets captured Copernicus’s interest from the start of his university studies. At college he purchased two sets of tables for calculating their positions and had these bound together, adding sixteen blank pages where he copied parts of a third table and wrote miscellaneous notes. (This custom volume and other remnants of his personal library, seized as spoils of the Thirty Years’ War, now belong to the University of Uppsala, Sweden. (Copernicus more than once explained his attraction to astronomy in terms of beauty, asking rhetorically, “What could be more beautiful than the heavens, which contain all beautiful things?” He also cited the “unbelievable pleasure of mind” he derived from contemplating “things established in the finest order and directed by divine ruling.”
“Among the many various literary and artistic pursuits upon which the natural talents of man are nourished,” he wrote, “I think the ones above all to be embraced and pursued with the most loving care concern the most beautiful and worthy objects, most deserving to be known. This is the nature of the discipline that deals with the godlike circular movements of the world and the course of the stars.”
ARISTOTLE’S UNIVERSE
As Copernicus learned in school, the world around him consisted of the four elements: earth, water, air, and fire. Far removed from these ordinary substances, the Moon and other celestial bodies consisted of a fifth essence, immune to change or destruction. In the perfect heavens, bodies moved with uniform circular motion.
The portrait of him now hanging in Torun’s town hall cuts a youthful, handsome figure. Based on a purported self-portrait that disappeared long ago, it shows Copernicus dressed in a red jerkin, with glints painted into his dark eyes and dark hair. (The light in each brown iris reflects, on close inspection, the tall Gothic windows of the rooms he frequented.) He had a long nose, a manly shadow above his full lips, and a faint scar extending from the corner of his left eye up into the eyebrow. This mark encouraged archaeologists in 2005, who picked out his skull among the litter of remains under the church where he had lain buried. A double dent above the skull’s right eye socket—not the left one—seemed to affirm their identification, since every portraitist sees himself as his mirror’s image.
In September 1496, again at his uncle’s command, Copernicus traveled to Italy to study canon law, concerning the rights and duties of the clergy, at the University of Bologna. Only one year into this enterprise, he became a canon himself. The death of one of the sixteen Varmia canons created a vacancy, and Bishop Watzenrode used his connections to win Copernicus the office in absentia. As the fourteenth canon of the Cathedral Chapter—effectively a trustee in the rich and powerful governing body of the Varmia diocese—Copernicus could now collect an income independent of his allowance.
He lodged in Bologna with the local astronomy professor, Domenico Maria Novara, whom he assisted in nightly observations. Together they watched the Moon pass in front of the bright star Aldebaran (the eye of Taurus the Bull) on March 9, 1497, and Copernicus recorded in his notes how the star hid “between the horns of the moon at the end of the fifth hour of the night.”
At the conclusion of his law studies, he visited Rome in the summer of 1500 for the jubilee year celebrations. He and other pilgrims tripled the population of the Holy City, where a crowd of two hundred thousand knelt to receive the Easter Sunday blessing of Pope Alexander VI. Still in Rome on November 6, Copernicus observed and recorded a partial lunar eclipse. He also lectured in Rome about mathematics to students and experts alike. But his future with the Church had already been decided. July 27, 1501, found him at a meeting of the Cathedral Chapter in Varmia, along with his older brother, Andreas, who had also attained a canonry there, courtesy of Uncle Lukasz. Both young men requested leave to return to Italy for further education and received the chapter’s blessing. They set out almost immediately for Padua, where Copernicus studied medicine in preparation for a career as “healing physician” to the bishop and canons of Varmia.
THE ZODIAC
The Earth-centered universe that Copernicus inherited is pictured in this frontispiece from one of his favorite books, the Epitome of Ptolemy’s Almagest, by Regiomontanus. He and oth
er astronomers measured the motions of the “wandering” stars—the planets, the Sun, and the Moon—through the band of “fixed” stars called the zodiac. The Sun took about one month to progress through each sign, completing the circuit from the ram, Aries, to the fishes, Pisces, in a year. Since the actual constellations vary considerably in size, astronomers arbitrarily assigned the same one twelfth of a circle, or 30°, to each zodiac sign.
In his novel Doctor Copernicus, John Banville imagines the brothers equipping themselves for their journey “with two stout staffs, good heavy jackets lined with sheepskin against the Alpine cold, a tinderbox, a compass, four pounds of sailor’s biscuit and a keg of salt pork.” This and other rich descriptions—one of which pictures “Nicolas” sewing gold coins into the lining of his cloak for safekeeping—leap the gaps in the true life story. Historians have pieced that together from his few published works and the scattered archives where he left his name. His lifetime of correspondence comes down today to just seventeen surviving signed letters. (Of these, three concern the woman who lived with him as cook and housekeeper, and probably concubine as well.)
“The inns were terrible, crawling with lice and rogues and poxed whores,” Banville continues the brothers’ travel narrative. “And then one rainy evening as they were crossing a high plateau under a sulphurous lowering sky a band of horsemen wheeled down on them, yelling. They were unlovely ruffians, tattered and lean, deserters from some distant war. … The brothers watched in silence their mule being driven off. Nicolas’s suspiciously weighty cloak was ripped asunder, and the hoard of coins spilled out.” It could all have happened, just that way.
As a medical student at the University of Padua, Copernicus learned therapeutic techniques, such as bloodletting with leeches, aimed at balancing the four bodily humors: blood, phlegm, black bile, and yellow bile. All manifestations of health or disease stemmed from an excess or deficiency of one or more of these fluids. Even gray hair was caused by “corrupt humors” and could be postponed with the proper prescription. Copernicus also watched anatomical dissections, studied surgical procedures, and took instruction in the application of astrology to diagnosis and treatment. His textbooks, which were still with him at his death and mentioned in his will, included the 1485 edition of Breviarium practicae by Arnaldus of Villanova, a thirteenth-century physician and alchemist.