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[Ill.u.s.tration: DuRER NATIVITY ]
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Some expressions of the women of the Renaissance are famous for their wit and aptness. The famous reply of one of them, the Princess Christina of Denmark, may be taken as evidence that witty power of expression was not confined to the women of the Southern countries.
Her picture by Holbein, "The Lady with the Cloak," is so well known that we seem to be able to recreate her personality rather completely.
She was approached by the amba.s.sadors of Henry VIII after the death of Jane Seymour with a proposal of marriage. Indeed, Holbein's picture was made for the purpose of giving the uxorious Henry an idea of the charms of the young woman. She was only eighteen at the time, but she was already the widow of Francesco Sforza, and she is said to have replied she would be quite willing to be the Queen of England if she had two heads and could be sure of retaining one of them. As she had only one, however, she could not take any risks in the matter. Julia Cartwright's life of her, recently published, shows what a clever woman of the Renaissance she was. Her reply is quite worthy of the Italian ladies of the time, some of whom were noted for their rather biting wit. One of the n.o.bility in Italy having said that man's duty was to fight and not to take part in social ceremonies, one of the Gonzagas said; "It is too bad, then, that he does not hang himself up in a closet with his armor whenever he is not actually engaged in warfare."
It is often a.s.sumed that intellectual development, and especially the higher education, has a tendency to take women away from that devout att.i.tude of mind which makes them religious. There are many examples in the Renaissance time, however, which serve to disprove this idea.
The smaller and more superficial minds may be thus affected. It is not true for the larger, more profound intelligence. St. Teresa, in her directions to the Mothers of houses as regards the reception of postulants, said: "Where there is ignorance and piety do not forget that the piety may evaporate and the ignorance remain." Many of the best-known intellectual ladies of the Renaissance time were deeply pious, Vittoria Colonna is a typical example, so in spite of the apparent testimony of her famous book to the contrary is Marguerite of Navarre.
[Ill.u.s.tration: VIVARINI, ST. CLARE]
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Lucretia Tornabuoni, the mother of Lorenzo the Magnificent, wrote some charming religious verse. The difference of opinion between Clarice dei Orsini, the wife of Lorenzo, and Politian as regards the teaching of religion to her children, in which she came off victor, is well known. Above all, these women were all close to the religious women of the time. Many of them spent some days every year at least, often some weeks, in favorite convents. They took their rest by following the daily exercises of the monastic life in various convents. Vittoria Colonna was noted for this, and during her widowhood spent very much time in this way. Nothing that I know contradicts so completely the slanders as to convent life at this time as these intimate relations with the religious.
It is noteworthy that in our country and time, just in proportion as education for women is widely diffused, the practice of more intimate relations with convents grows more common. Many women of the world, teachers, writers, take a few days each year now for a retreat in a convent. Not a few of those who enter religion are very well educated.
A great many of those who belong to the teaching orders are thoroughly trained, and often fine experts in their specialties. In the Renaissance period the daughters of the great n.o.ble houses sometimes entered religious orders. Not infrequently they met with opposition, and especially parental and family influence was exerted to divert them from their purpose. Paola and Cecilia Gonzaga both became religious. There was considerable family opposition, especially on her father's part, against Cecilia's accomplishment of her purpose, but her great teacher, Vittorino da Feltre, one of whose favorite pupils Cecilia was, took her side. When her father insisted on finding a husband for her, Vittorino urged that women should be allowed to choose their careers for themselves, and above all, if they felt the call to the spiritual and intellectual life, should be given the opportunity for the self-development that the peace and ordered life of the cloister afforded.
Burckhardt has summed up the qualities of the women of {342} the Renaissance in a single sentence, that is worth while recalling. So much is said about the influence of the study of the cla.s.sics in producing pagan ideas and looseness of morals and relaxation of old ethical standards during the Renaissance that it is well to recall what this deep student of the time thought. His words will be found to corroborate and sum up the character that we have been trying to paint of the women of the Renaissance in these pages:
"Their distinction consisted in the fact that their beauty, disposition, education, virtue and piety combined to make them harmonious human beings."
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CHAPTER X
PHYSICAL SCIENCE OF THE CENTURY
While it is universally conceded that the Renaissance was a supremely great period in all the arts and literature, in education and scholars.h.i.+p, and that its geographical discoveries made it noteworthy from another standpoint, there is a very prevalent impression that it was distinctly lacking in scientific development and that indeed the proper att.i.tude of mind for successful scientific investigation was a much later evolution. Most of the discoveries of even basic notions in science are almost universally thought to have been reserved for our time or at least for generations much nearer to us than Columbus'
Century.
Nothing could well be less consonant with the actual history of science than any such impression. At many times before ours man has made great scientific progress. The greatest mystery of human history is that often after great discoveries were made they were somehow lost sight of. Over and over again men forget their previous knowledge and have to begin once more. There was one of these magnificent developments of scientific thought in every department during Columbus' Century and discoveries were made and conclusions reached which revolutionized other modes of scientific thinking just as much as Columbus' discovery of America revolutionized geography, or the work of Raphael or Michelangelo and Leonardo revolutionized the artistic thought of the world.
When we recall that it was at this time that Copernicus set forth the theory which has probably more influenced human thinking than any other and that this discovery developed directly from the mathematics of the time and while Vesalius revolutionized anatomy, the discovery of the circulation of the blood began a similar revolution in physiology and the foundations of botany and of modern chemistry in their relations to medicine were laid, some idea of the greatness of the {344} scientific advance of this period will be realized.
Mathematics, particularly, developed marvellously and it is always when new horizons are opening out in mathematics that the exact sciences are sure to have a period of wonderful progress. Beautiful hospitals were erected and whenever there are good hospitals, surgery makes progress and that care for the patient which const.i.tutes the essential part of medicine at all times, receives careful attention.
Above all the men of the Renaissance took it on themselves to edit and translate and publish the ancient cla.s.sics of science and make them available for the study of their own and subsequent generations. The debt which the modern world owes to the Renaissance in this matter is only coming to be properly realized as a consequence of our own development of scholars.h.i.+p in this generation. Only the profound scholar is likely to appreciate properly how much we are indebted to the patient, time-taking work of this period in making books available. Not only the ancient cla.s.sics but also the works of the Middle Ages on scientific subjects were all published. The early Christian scholars, the Arabians, and above all, the great teachers of the later Middle Ages were edited and printed as an enduring heritage for mankind.
The index of the feeling of the time toward physical science as well as the interest of the scholars of the period in nearly every phase of it is ill.u.s.trated by the life of Cardinal Nicholas of Cusa, who is usually known as Cusa.n.u.s. He was a distinguished German churchman who was made Bishop of Brixen and afterwards Cardinal and who had the confidence of the Popes to such a degree that he was sent out as Legate for the correction of abuses in Germany. He was particularly interested in mathematics and the great German historian of mathematics. Cantor, devotes a score of pages to the advances in mathematics which we owe to Cusa.n.u.s. According to tradition during his journeys over the rough roads in the rude carriage of the time, he studied the curve described through the air by a fly as it was carried round the wheel after alighting on the top of it. He recognized this as a particular kind of curve which we know now as the cycloid and he studied many of its peculiarities and suggested its mathematical import.
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He was particularly interested in astronomy and declared that the earth was round, was not the centre of the universe and that it could not be absolutely at rest. As he put it in Latin: _terra igitur, quae centrum esse nequit, motu omni carere non potest._ He described very clearly how the earth moved around its own axis, and then he added what cannot but seem a surprising declaration for those who in our time think such an idea of much later origin, that he considered that the earth itself cannot be fixed, but moves as do the other stars in the heavens, _Consideravi quod terra ista non potest esse fixa sed movetur ut aliae stellae._ More surprising still, he even seems to have reached by antic.i.p.ation some idea of the const.i.tution of the sun.
He said: "To a spectator on the surface of the sun the splendor which appears to us would be invisible since it contains as it were an earth for its central ma.s.s with a circ.u.mferential envelope of light and heat and between the two an atmosphere of water and clouds and of ambient air."
These expressions occur mainly in a book _"De Docta Ignorantia,"_ in which the Cardinal points out how many things which even educated people think they know are quite wrong. His other books are on mathematics, though there is a little treatise on the correction of the calendar which shows how thoroughly the men of the time recognized the error that had crept into the year and how capable they were of making the correction. In a book of his on "Static Experiments" he has a very original discussion of laboratory methods for the study of disease which is eminently scientific, and which is described in the chapter on Medicine.
The life of George von Peuerbach, also Puerbach and Purbachius, the Austrian astronomer, one of Cardinal Nicholas' proteges who lived to be scarcely forty and whose greatest work was done just at the beginning of Columbus' Century, is an excellent index of the scientific spirit of the time. About 1440, when he was not yet twenty years of age, he received the degree of Master of Philosophy and of the Liberal Arts with the highest honors at the University of Vienna.
After this he seemed to have spent some time at postgraduate work in Vienna, especially in mathematics under Johann von Gmunden. Just about the beginning of Columbus' Century he went to {346} Italy. Cardinal Nicholas of Cusa became interested in him and secured him a lectures.h.i.+p on Astronomy at the University of Ferrara. During the next few years he refused offers of professors.h.i.+ps, at Bologna and Padua, because he wanted to go back to Vienna to teach in his alma mater.
There, with the true Renaissance spirit of non-specialism, he lectured on philology and cla.s.sical literature, giving special postgraduate courses in mathematics and astronomy. It was at this time that Johann Muller, Regiomonta.n.u.s, as he is known, came under his tutelage.
Purbach deserves the name that has been given him of the father of mathematical astronomy in modern times.
He introduced the decimal system to replace the c.u.mbersome duodecimal method of calculation, which up to his time had been used in mathematical astronomy. He took up the translation of Ptolemy's "Almagest," replaced chords by sines and calculated tables of sines for every minute of arc for a radius of 600,000 units. This wonderful work of simplification naturally attracted wide attention. Cardinal Bessarion was brought in touch with him during a visit to Vienna and was impressed with his genius as an observer and a teacher. He suggested that the work on Ptolemy should not be done on the faulty Latin translation which was the only one available in Vienna at the moment, but on some of the Greek ma.n.u.scripts of the great Alexandrian astronomer. He offered to secure them and also to provide for Purbach's support during the stay in Rome necessary for the study. The invitation was accepted on condition that his pupil Regiomonta.n.u.s should go with him. Unfortunately, however, Purbach died before his journey to Rome. His works were very popular in his own time and his commentary on the "Almagest of Ptolemy" as completed by Regiomonta.n.u.s became one of the standard text-books of the time. Altogether there are some twenty of his works extant and his "New Theory of the Planets" remained a favorite book of reference for astronomers even long after the publication of Copernicus. His industry must have been enormous but was after all not different from that of many of his contemporaries.
Astronomy was to be the great stimulating physical science of the early part of Columbus' Century and Purbach's successor {347} in the chain of scientific genius at this time was his pupil Johann Muller, or as he has come to be known from the Latinization of the name of the place of his birth, Konigsberg (in Franconia, not far from Munich), Regiomonta.n.u.s. As we have said, young Muller made his studies with Purbach at Vienna, became very much interested in astronomy and mathematics, at his master's suggestion accompanied Cardinal Bessarion to Italy and under his patronage took up the work of providing an abridgment of Ptolemy's great work, the "Almagest," in a Latin translation for those who might be deterred from the Greek.
Cardinal Bessarion became very much interested in him and gave him a chance to study in Italy. Muller chose Padua and spent nearly ten years there. Whenever anybody in almost any country in Europe wanted to secure opportunities for study beyond those afforded by his native land at this time he went down to Padua. Linacre, Vesalius, John Caius went there for medicine, Copernicus, a little later than Regiomonta.n.u.s, for mathematics and astronomy and it was the ardently desired goal of many a student's wishes. Muller spent nearly ten years in Italy, most of it at Padua and at the age of about thirty-five returned to Germany to take up his life work. He settled down in Nuremberg, where in connection with Bernard Walther he secured the erection of an observatory. Nuremberg, because of its fine work in the metals, was the best place to obtain mechanical contrivances of all kinds, and many of these were used for the first time for scientific purposes at this observatory. It became quite a show place for visitors and while Nuremberg was developing the literary and artistic circles in which the Pirkheimers, Albrecht Durer and the Vischers and Adam Kraft shone conspicuously, scientific interest in the city was at a similar high level.
Muller made a series of observations of great value in the astronomy of the time and subst.i.tuted Venus for the moon as a connecting link between observations of the sun, the stars and the earth. He recognized the influence of refraction in altering the apparent places of the stars and he introduced the use of the tangent in mathematics.
His most important work for the time, however, was the publication of a series of astronomical {348} leaflets, _"Ephemerides Astronomicae"_ in which his observations were published and also a series of calendars for popular information. These announced the eclipses, solar and lunar, for years before their recurrence and gave a high standing to astronomy as a science. Some of these leaflets even reached Spain and Portugal and encouraged Spanish and Portuguese navigators with the thought that they could depend on observations of the stars for their guidance at sea. In a way, then, Regiomonta.n.u.s' work prepared the path along which Columbus' discovery was made.
Regiomonta.n.u.s' work attracted so much attention that he was invited to Rome to become the Papal Astronomer and to take up the practical work of correcting the Calendar. Unfortunately he died not long after his arrival in Rome, though not before he had been chosen as Bishop of Regensberg (Ratisbon) as a tribute to his scholars.h.i.+p and his piety.
He thus became a successor of Albertus Magnus (in the bishopric), who had been in his time one of the profoundest of scholars and greatest of scientists. The tradition of appreciation of scholars.h.i.+p and original research had evidently been maintained for the three centuries that separate the two bishop scientists.
A distinguished scientific student born at Nuremberg the same year as Regiomonta.n.u.s was Martin Behem or Behaim, the well-known navigator and cartographer, who on his return to Nuremberg in 1493 made the famous terrestrial globe which was meant to ill.u.s.trate for his townsmen the present state of geography as the Spaniards and Portuguese had been remaking it. Behem's work is a striking testimony to the excellence of geographic knowledge at this time, and only for the preservation of this globe we could scarcely have believed in the modern time how correct were the notions of the scholars of the period with regard to the older continent at least.
One of the great physical scientists of this time is Toscanelli, the physician, mathematician, astronomer and cosmographer, over whose connection with Columbus such a controversy has raged in recent years.
He and Cardinal Cusa.n.u.s were fellow students at the University of Padua, where Toscanelli's course consisted of mathematics, philosophy and medicine. He settled down as a practising physician in Florence and took up {349} scientific studies of many kinds which brought him into connection not only with the students of science, but with the scholars and artists of the time. Brunelleschi and he were intimate friends, but he was well known outside of Italy, and Regiomonta.n.u.s often consulted him. His services to astronomy consist in the painstaking and exact observations on the orbit of the comets of 1433, 1449-50 and especially of Halley's comet on its appearance in 1456 and of the comets of May, 1457, June, July and August of the same year.
These show a most accurate power of astronomical observation and profound mathematical knowledge for that time. His famous chart indicated just how a navigator might reach the coast of India by sailing westward, and Columbus is said to have carried a copy of this chart with him on his first voyage. Whether this is true or not, there is no doubt of Toscanelli's place in the history of science because of original work in astronomy, geodesy and geography.
The most important protagonist of physical science during Columbus'
Century, however, was undoubtedly Copernicus. Columbus gave the men of his time a new world, but Copernicus gave them a new creation. When early in the sixteenth century he published a preliminary sketch of his theory, one of his ecclesiastical friends remarked to him that he was giving his generation a new universe. There has probably never been a theory advanced which has changed men's modes of thinking with regard to the world they live in and their relation to it as the Copernican hypothesis has done, though it must not be forgotten that there are some as yet insuperable difficulties which keep it still in the cla.s.s of scientific hypotheses.
The earth had up to this time been universally thought of as the centre of the universe, much more important than any of the other bodies, sun, moon or stars, and all the others were thought to move around it. Their apparent movement was due to the rotation of the earth, which was quite unrecognized. The immense distances of s.p.a.ce were entirely undreamt of. In the new order of thinking the earth became a minor planet of small size in our solar system which was of inconspicuous magnitude when compared to the totality of the other bodies of the universe. The acceptance of the new theory sank man in his own estimation very considerably. The change of point of view of {350} the meaning of the universe necessitated by the Copernican theory was ever so much greater than that demanded by evolution in our time.
It took two centuries for men to adjust their thinking to these new ideas. Francis Bacon, a full century after Copernicus' time, declared emphatically that the Copernican theory did not explain the known facts of astronomy as well as the Ptolemaic theory. In Bacon's time Galileo was the subject of persecution and the reason for the persecution was that he was advancing a doctrine which no other great astronomer of his time accepted, and advancing it for reasons which have not held in the after-time. The Copernican theory came eventually to be accepted for quite different reasons from those advanced by Galileo.
How Copernicus succeeded in coming to this magnificent generalization is indeed hard to understand. It is easier to get some notion of it, however, when his achievement is taken in connection with what was being done all around him at this time. Living in a century when great men were accomplis.h.i.+ng triumphs in painting, sculpture, architecture that have been the wonder of the world ever since, and when geography was being revolutionized, and nearly every science awakened, it is not surprising that he should have reached a height of mathematical and astronomical expression beyond any that men had ever conceived before and that he should have surpa.s.sed many of the generations to come after him, by the clearness of his intuition of the astronomical mystery of the universe.
Copernicus had not made many observations nor were such observations as had been made by him worked out with that painstaking accuracy which might be thought necessary to reach a great new conception of the universe. He had the genius to see from even the few and imperfect data that he had at hand what the true explanation of the diverse phenomena of the heavens was. He had no demonstrations to advance. He argued merely from a.n.a.logy. Even Galileo, a century later, admitted to Cardinal Bellarmine that he had no strict demonstration of his views to offer, but that "the system seems to be true." While the feeling of many scientists in the modern time is that great discoveries come from patient {351} acc.u.mulation of accurate observations in large numbers, the history of science shows that almost invariably the epochal steps in progress have come from men who were comparatively young as a rule and who were not overloaded with the information of their time. The great artists of the Renaissance could probably have given no better reasons for their artistic conceptions than Copernicus for his stroke of genius, but they were all working at a time when somehow men were capable as they never have been since of these far-reaching intellectual achievements.
Copernicus was a Pole who, like other students of his time, gladly welcomed the opportunity to go down to Italy for post-graduate work, studied with Novara at Padua mathematics and astronomy and was quite willing to add the study of medicine, because by so doing he could secure an extension of the length of time he would be allowed to remain in Italy. He then returned to be a canon of the Cathedral of Frauenberg, and spent forty years in quiet patient observation and in the practice of his medical profession not for money, but for the benefit of the poor and such friends of the chapter of the Cathedral as he was under obligations to because of the years they had supported him in Italy. He probably reached his great astronomical theory when he was about thirty. He did not publish the preliminary sketch of it for twenty-five years. He did not publish his great book until just before his death, keeping it by him, making changes in it and while thoroughly convinced of its importance, quite sure that, owing to its lack of definite demonstration, it would not be generally accepted.
Like so many of these geniuses of the Renaissance he was a simple kindly man who had many good friends among those around him and who had one of the very happy lives accorded to those who, having some great thought and great work to occupy themselves with, have daily duties that afford them diversion and bring them into contact with friends in many ordinary relations in life. His humility of heart and simplicity of character, as well as his deep religious faith, can be very well appreciated from the prayer which at his own request was the only inscription upon his tombstone: "I ask not the {352} grace accorded to Paul, not that given to Peter; give me only the favor Thou didst show to the thief on the Cross."
His att.i.tude toward the reform movement, twenty years of which he lived through in Germany, is interesting. He was an intimate friend of Bishop Maurice Ferber of Ermland, who kept his see loyal to Rome at an epoch when the secularization of the Teutonic Order and the falling away of many bishops all around him make his position and that of his diocese noteworthy in the history of that place and time. Copernicus continued loyal to the old Church and in 1541 his great book _"De Revolutionibus...o...b..um Celestium"_ was dedicated to Pope Paul III, who accepted the dedication and until the Galileo matter brought Copemicanism prominently into question there was never any thought of Copernicus' book as containing matters opposed to faith. It was then placed on the _Index_, but only until some minor pa.s.sages should be corrected which set forth the new theory as if it were an astronomical doctrine founded on facts and demonstrations and not a hypothesis still to be discussed by scientists.
The scientific spirit of this century is often scouted because in spite of their scientific knowledge many of the astronomers and mathematicians of this time as well as, of course, other educated men following their example, could not quite rid themselves of the idea that the stars were powerful influences over man's life and health.
The history of this idea, however, minimizes the objection. All down the centuries men like Roger Bacon, Albertus Magnus, Nicholas of Cusa, Marsilio Ficino and Pico della Mirandola insisted that there could be nothing in what we now call astrology. Men parted with the older ideas very slowly, however. Almost a hundred years after Columbus' Century even Galileo made horoscopes and seems to have thoroughly believed in them, though some of his prophecies were sadly mistaken. Kepler drew up horoscopes, confessing that he had not much confidence in them but that they were paid for much better than other mathematical work and he sadly needed the money. Lord Bacon could not quite persuade himself that there was nothing in astrology. As late as after the middle of the eighteenth century Mesmer's thesis for graduation in medicine at the University of Vienna, which {353} at that time had one of the best medical schools of Europe, was on the influence of the stars on human const.i.tutions. It was accepted by the faculty and he got his degree.
Even in our time, though now the educated contemn, the ma.s.s of the people still have not entirely rejected astrology. The men of Columbus' Century can scarcely be thought less of for having accepted it, though many of the scientists of the time did not.