Michael Fowler,
UVa Physics
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Johannes Kepler was born on December 27, 1571, a premature child. To be precise, according to his own records, the pregnancy lasted 224 days, 9 hours and 53 minutes. (This rather odd piece of information, and the quotes from Kepler's horoscopes for his family given below, I found in Koestler's book, reference 1.) It should be clear from this obsession with the precise time of birth and conception that Kepler took astrology fairly seriously. He was born in Weil, in Swabia, a wine region in southwest Germany not far from France. Unfortunately, the family he was born into makes Tycho's early life look tranquil by comparison. Kepler's grandfather was Mayor of Weil, Kepler describes his grandmother as "restless, clever and lying, but devoted to religion; slim and of a fiery nature; vivacious, an inveterate troublemaker; jealous, extreme in her hatreds, violent, a bearer of grudges...and all her children have something of this". His father he describes as "...a man vicious, inflexible, quarrelsome and doomed to a bad end. Venus and Mars increase his malice. Saturn in VII made him study gunnery..." Kepler's mother he describes in the family horoscope as "small, thin, swarthy, gossiping and quarrelsome, of a bad disposition". His mother collected herbs and made potions which she believed had magical powers. She was raised by an aunt who was burned at the stake as a witch, and Kepler's mother narrowly escaped a similar fate herself (see ref 2, page 159: Kepler had to hire several lawyers to defend his seventy-year-old mother incarcerated on a charge of witchcraft, and "Another woman born in the same town as Kepler's mother, and accused of complicity with her, had already left one of her thumbs stuck in the rack".)
As a seven-month child, Kepler was sickly from birth, and contracted smallpox when very young. His vision was severely defective, and he had various other illnesses fairly constantly, some of which may have been hypochondria. He took twice as long as normal children to get through elementary latin. He did a little better when he got to the higher school at Maulbronn, a school which only half a century earlier was haunted by the ill-famed Dr. Faustus (ref 2).
Kepler went to the University of Tuebingen, a Protestant institution, where he studied mainly theology and philosophy, but also mathematics and astronomy. (The Dukes of Wuerttemberg, after becoming Lutheran, put in place an efficient educational system, with grants and scholarships for the poor, to ensure the universities could supply well educated clergymen capable of defending the new faith in the religious controversies raging at the time.) At the university, Kepler's exceptional intellectual abilities became apparent. He greatly admired the astronomy professor Maestlin, who publicly taught the Ptolemaic scheme, but privately believed Copernicus. Kepler himself defended Copernicus' scheme in a public debate. Unfortunately for him, that ensured that he would not be offered a faculty position at Tuebingen when he graduated. (Luther himself had mocked at Copernicus' scheme, and quoted scripture to prove it wrong.) Instead, Kepler was offered a professorship of astronomy in faraway Graz, Styria (now part of Austria), where he went in 1594. One of the duties of this professorship was to make astrological predictions. Despite his earlier efforts at horoscopes, he wrote "a mind accustomed to mathematical deduction, when confronted with the faulty foundations (of astrology) resists a long, long time, like an obstinate mule, until compelled by beating and curses to put its foot into that dirty puddle" (ref 1, page 245). Nevertheless, he predicted a cold winter, and an invasion by the Turks. Both predictions turned out to be correct. He was treated with a new respect, and his salary was increased.
While lecturing to his math class in Graz, contemplating some geometric figure involving concentric circles and triangles on the blackboard, Kepler suddenly realized that figures of the type shown here determine a definite fixed ratio between the sizes of the two circles, provided the triangle has all sides equal, and a different ratio of sizes will occur for a square between the two circles, another for a regular pentagon, and so on.
He thought this might be the key to the solar system. He truly believed in the Copernican system, so he saw the planetary orbits as six concentric circles. A natural question to ask is: why did the Creator make the orbits the particular sizes they are? He felt the universe would somehow show mathematical beauty or symmetry. Arguing in a way that Pythagoras and Plato would have sympathized with, he suggested that the orbits might be arranged so that regular polygons (triangles, squares, etc.) would just fit between adjacent ones, and maybe somehow this reflected some invisible underlying structure holding it all together. Disappointingly, he found it just didn't work out---the ratios were wrong. Then he had a real inspiration. The universe was really three-dimensional, and instead of thinking about circles, he should be thinking about spheres, with the planetary orbits being along the equators. Thinking in three dimensions, the analogue of the above diagram would be two concentric spheres with a tetrahedron between them, so that the outer sphere passes through the vertices of the tetrahedron, and the inner sphere touches all its sides, but is completely contained in the tetrahedron. Now came the really exciting part-there were just six planets, so five spaces between spheres, and there are just five regular solids! Thus, if the distances came out right, the theory provided a complete explanation, in terms of an elegant geometric model, of why there are just six planets, and why they are spaced as we find them. Actually, the distances still don't come out right, especially for Jupiter, but Kepler was so sure of the rightness of his scheme, that he blamed the discrepancies on errors in Copernicus' tables. He modestly titles his work Mysterium Cosmographicum--the mystery of the universe (explained). The crucial illustration from his book is shown below, the outer sphere being the orbit of Saturn, and the central part is shown magnified at top right.
Unfortunately Kepler (who described himself as a little lap dog) was barking up the wrong tree. We now understand that there are no compelling geometrical reasons why the planets are at just the distances they are from the sun. If the solar system were to be disturbed in some way, for example if another star were to come close, the planetary orbits would change. But it is unreasonable to think Kepler should have realized this. To him, the solar system was the central, most important part of creation, and one would expect the Creator to come up with something very special, reflecting the eternal truths of number and geometric form. In fact, Kepler's approach is quite appealing in the context of modern physics---the hydrogen atom has a single electron in orbit around a proton, like a one-planet solar system, and quantum mechanics only allows the electron to describe certain orbits, which are geometrically determined! Kepler would have been a very good quantum physicist if he had been born three centuries later.
Kepler asked himself another, more fruitful, question concerning the planetary orbits: why did the outer planets move more slowly? Saturn's orbit is about twice the size of Jupiter's, but Saturn takes substantially more than twice as long to go once around. His response to this question was:
"...we must choose between two assumptions: either the souls which move the planets are the less active the farther the planet is removed from the sun, or there is only one moving soul in the center of all the orbits, that is the sun, which drives the planet the more vigorously the closer the planet is, but whose force is quasi-exhausted when acting on the outer planets because of the long distance and the weakening of the force which it entails." (in ref. 1, p 261)
In the second edition of the book, which he wrote when he was fifty, he stated that such souls "do not exist" and added:
"If we substitute for the word "soul" the word "force" then we get just the principle which underlies my physics of the skies...For once I firmly believed that the motive force of a planet was a soul...Yet as I reflected that this cause of motion diminishes in proportion to distance, just as the light of the sun diminishes in proportion to distance from the sun, I came to the conclusion that this force must be something substantial-"substantial" not in the literal sense but...in the same manner as we say that light is something substantial, meaning by this an unsubstantial entity emanating from a substantial body."
What we are seeing here is a gradual emergence from medieval concepts. At first, Kepler thought the planets moved because they had souls-they were alive, magical, not just lumps of matter. Later, he realized a more mechanical approach was more appropriate. He wrote in a letter:
"My aim is to show that the heavenly machine is not a kind of divine, live being, but a kind of clockwork, insofar as nearly all the manifold motions are caused by a most simple, magnetic, and material force, just as all motions of the clock are caused by a simple weight. And I also show how these physical causes are to be given numerical and geometrical expression."(ref. 1, page 345)
However, in quoting Kepler's later appreciation of the mechanistic nature of the solar system we are getting rather ahead of our story. Kepler's main interest at the time of publication of Mysterium Cosmographicum and after was to get hold of Tycho's data, which he felt would confirm his picture of the solar system. Before he had ever met Tycho, he wrote to his mentor Maestlin:
"My opinion of Tycho is this: he is superlatively rich, but he knows not how to make proper use of it, as is the case with most rich people. Therefore, one must try to wrest his riches from him." (ref. 1, page 280)
In 1598, Kepler's school in Graz, along with other Lutheran institutions, was closed down by the young Archduke Ferdinand of Hapsburg, who had decided to cleanse the Austrian provinces of the Lutheran heresy. Kepler was allowed to stay for a while, but the next year he was given the choice of embracing Catholicism or being expelled from Austria. He wanted to go back to Protestant Tuebingen, but they didn't want him, because of his known belief in Copernicanism. Tycho invited him to come work with him, so he left for Prague on January 1, 1600.
When he began working with Tycho's group, Kepler realized it would not be so easy to use Tycho's masses of data. Tycho was very secretive: he had his own agenda, which was to establish his own model of the solar system, an intermediate one, in which the sun goes around the earth once a year, and all the other planets go around the sun. He was not anxious for his data to be used to support a Copernican model. However, Kepler was happy that Tycho suggested he work on the orbit of Mars, which was one of the least circular orbits, and hence a good test of new models, and for which Tycho would be obliged to give him a substantial amount of data. Kepler made a bet that he would understand the orbit in eight days, actually, it took him eight years.
The next year, 1601, Tycho's lifestyle caught up with him. He became very ill at a banquet, and a few days later died in agony of a bladder infection. Tycho's heirs were anxious to make as much money as possible out of the estate, and the impoverished Kepler realized that if he didn't act immediately, he would never get to use most of Tycho's data. As he wrote in a letter in 1605: "I confess that when Tycho died, I quickly took advantage of the absence, or lack of circumspection, of the heirs, by taking the observations under my care, or perhaps usurping them..." (ref 1, page 280)
References
1. Arthur Koestler, The Sleepwalkers, Arkana Books, London, 1989. I have used this book for many of the facts presented here. It contains many references to primary sources, including Kepler's own extensive writings on his life as well as on science.
2. Carola Baumgardt, Johannes Kepler: Life and Letters, Gollancz, London 1952.
3. Eric Rogers, Physics for the Inquiring Mind, Princeton.