Discussion 6
Lecture 10: The Scientific
Revolution, 1543-1600
Why then do we hesitate to grant [the Earth] the
motion which accords naturally with its form, rather
than attribute a movement to the entire universe
whose limit we do not and cannot know? And why
should we not admit, with regard to the daily
rotation, that the appearance belongs to the
heavens, but the reality is in the Earth?
---Copernicus, On the Revolutions of the Heavenly
Bodies (1543)
One of the most important developments in the western
intellectual tradition was the Scientific Revolution. The
Scientific Revolution was nothing less than a revolution
in the way the individual perceives the world. As such,
this revolution was primarily an epistemological
revolution -- it changed man's thought process. It was
an intellectual revolution -- a revolution in human
knowledge. Even more than Renaissance scholars who
discovered man and Nature (see Lecture 1), the
scientific revolutionaries attempted to understand and
explain man and the natural world. Thinkers such as the
Polish astronomer Nicholas Copernicus (1473-1543), the
French philosopher René Descartes (1596-1650) and the
British mathematician Isaac Newton (1642-1727)
overturned the authority of the Middle Ages and the
classical world. And by authority I am not referring
specifically to that of the Church -- the demise of its
authority was already well under way even before the
Lutheran Reformation had begun. The authority I am
speaking of is intellectual in nature and consisted of the
triad of Aristotle (384-322), Ptolemy (c.90-168) and
Galen (c.130-201). The revolutionaries of the new
science had to escape their intellectual heritage. With
this in mind, the revolution in science which emerged in
the 16th and 17th centuries has appeared as a
watershed in world history. The long term effects of
both the Scientific Revolution and the modern
acceptance and dependence upon science can be felt
today in our daily lives. And notwithstanding some
major calamity -- science and the scientific spirit will be
around for centuries to come. (For an excellent
overview of the Scientific Revolution see Robert Hatch's
The Scientific Revolution Home Page.)
In 1948, the British historian Herbert Butterfield (1900-
1979) prepared a series of lectures to be delivered at
the History of Science Committee at Cambridge. These
lectures became the foundation for his book, The
Origins of Modern Science. In the Preface to this work,
Butterfield wrote that:
The Revolution in science overturned the authority
in not only of the middle ages but of the ancient
world -- it ended not only in the eclipse of scholastic
philosophy but in the destruction of Aristotelian
physics.
The key word here, I suppose, is authority. The
Renaissance and Reformation also attacked the
stranglehold of medieval authority but with quite a
different purpose and with decidedly different results.
However, Butterfield continues:
The Scientific Revolution outshines everything since
the rise of Christianity and reduces the Renaissance
and Reformation to the rank of mere episodes, mere
internal displacements within the system of
medieval Christianity.
Consider the period in which Butterfield makes this
statement. It's 1948, just a few years after Hiroshima --
78,000 men, women and children died within fifteen
minutes of the dropping of the atomic bomb. This is
what science has given us. And although I doubt
whether Butterfield, civilized Englishman that he was,
would have gloated over this fact of neat and efficient
killing, the fact remains that this was science in action.
There are numerous questions we could ask ourselves
about the Scientific Revolution: why it occurred? what
forces produced it? why was it so revolutionary? why
was it stronger in the Protestant North? But to my mind,
before we can even begin to cope with these questions
we must ask a much more basic question: What is
science?
Science is no doubt with us today -- it surrounds our
daily lives to such an extent that we now take it as a
given. We expect science to be, to exist. Its effects and
products touch the statesman and the soldier, the
house husband and the grocer. Science has given us
nylon, fluoride, latex paint as well as 747s, ever-faster
microchips and PEZ. But science has also given us
fluorocarbons, heroin, nuclear waste, dioxin, sarin gas
and the atomic bomb. Science can be a mixed blessing -
- with much that is good comes much that is clearly
bad. But, what do we mean by science?
Science is faith. And the Gospel of that faith was written
by Copernicus, Galileo, Newton, Darwin, Einstein and
others. We are certainly not all scientists. I know I'm not
a scientist. But yet, I'm sure that scientists are busy at
work solving problems, the solution to which will help
me in some way. Perhaps scientists can improve our
situation here on earth, just as the Gospels perhaps did
almost two millennia ago. A scientist is an expert and
for some reason we have grown to trust experts. The
scientists, the technicians, the experts -- they must
know the answers to our questions.
We are surrounded by science whether we recognize it
or not. Just about everything we see, touch, smell and
hear, is a product of science. Furthermore, science has
a language all its own, a language which uses
expressions like: rational, method, methodological,
systematic, rules, laws, behavior, experts, technology
and so on.
What I would like to suggest is that for the non-scientist,
science is an idea. And this idea -- science -- gives us
ways in which to think about and explain our world and
ourselves. Science provides a world view, a way of
making sense out of the apparently random and
meaningless experience of our lives.
The origins of this world view emerged full blown in the
Scientific Revolution of the late 16th and 17th centuries.
The Revolution itself was European -- it was
cosmopolitan. Its short term effects were felt
throughout the Continent and in England. And today,
barely three or four centuries after the fact, there are
few areas on the globe that remain untouched by
modern science, whether for good or bad.
In the 16th and 17th centuries, scientists, theologians,
philosophers and mathematicians were engaged in a
vigorous debate over the natural world. Not so much
man, but Nature. After all, the Renaissance had refined
the dignity of man as perhaps distinct from the human
depravity that the Church had preached. Nature -- the
new focus was Nature. But why was this a subject for
examination? Why had Nature become the new object
of study? The reasons for this are complicated but for
now I will suggest that answer lay with the Christian
matrix. More specifically, the new focus on Nature was a
direct result of the collapse of the Christian matrix, and
this was the result of a combination of forces which
produced intellectual change. To be brief, these forces
were the Renaissance, Reformation (see Lecture 3), the
Age of Exploration (see Lecture 2) and the spirit of
capitalism. The major obstacle faced by the scientific
revolutionaries was one of knowledge -- it was a
specifically epistemological question. If an older world
view was to break down, then something would have to
take its place. A new human identity was required -- it
was essential to the changes in the intellectual climate.
How could the world be known? Another way of putting
this is to say that if the Renaissance had discovered
man and Nature, then it was up to the scientific
revolutionaries to verify their knowledge of man and
Nature.
What did science mean to the scientific revolutionaries?
One of the problems inherent in this question is that the
revolutionaries rarely used the word science. Instead,
they talked and wrote about natural philosophy or the
philosophy of nature. Nature, to them, meant the
natural world, that is, what was natural, what was not
made by human hands. I would suggest that using the
expression the philosophy of nature was really a
hangover from the medieval world. In other words,
questions of science were subsumed under the study of
philosophy, and since medieval man called the
phenomenal world Nature, then it was quite logical to
refer to the study of Nature as the philosophy of Nature.
Above all, science meant astronomy and mathematics.
These seemed to be the only two fields of study that
embraced both laws and the explanation of those laws.
Astronomy and mathematics have their own symbols --
they have their own language. This language, though
difficult, is stronger than any other language because of
its power to be understood by people who speak
different languages. In other words, the language of
science is universal. Whereas Charlemagne (742-814)
had created a scholarly language -- we call it, medieval
Latin -- the scientific revolutionaries created a language
of science, and we call this language, mathematics. The
legacy of all this to the modern world -- to our world --
was the scientific way of thinking -- it is a process of
thought which is technical, mathematical, logical and
precise. It's complicated too -- it's difficult for the non-
specialist to understand. But perhaps not that difficult.
Consider the following definition of man given by R.
Buckminster Fuller (1895-1983), the father of the
geodesic dome:
Man is a self-balancing, 28-jointed adapter-base
biped, and electro-chemical reduction plant, integral
with the segregated stowages of special energy
extracts in storage batteries, for subsequent
activation of thousands of hydraulic and pneumatic
pumps, with motors attached; 62,000 miles of
capillaries, millions of warning signal, railroad and
conveyor systems, crushers and cranes, and a
universally distributed telephone system needing no
service for seventy years if well managed, the
whole extraordinary complex mechanism guided
with exquisite precision from a turret in which are
located telescopic and microscopic self-registering
and recording range-finders, a spectroscope, etc.
This is science gone absolutely crazy. Of course, such a
definition of man ignores his nature -- his emotions,
dreams, joy, sadness, successes and failures. In fact,
Fuller seemed to ignore everything that made the
individual fully human. It is a mechanical explanation of
man -- man as machine. It is also an explanation of man
that would not have been possible had it not been for
an intellectual development we call the Scientific
Revolution. The irony, however, is that if somehow we
could have gotten Galileo and Fuller together over
lunch, Galileo would have perhaps found Fuller
positively mad (then again, Fuller would have not been
the type of person he was without Galileo as a
predecessor).
Before we talk about the scientific revolutionaries, the
implications of their work and their world view, it is
necessary to examine the medieval world view. It was,
after all, the world view of medieval man that the
scientific revolutionaries made the deliberate attempt
to overthrow. The medieval world view -- the linchpin of
the Christian matrix -- was fashioned from the ideas of
four men. Two of them were from the ancient world --
Aristotle and Ptolemy. And the other two were of the
medieval world -- St. Thomas Aquinas (c.1225-1274)
and Dante Alighieri, (1265-1321).
According to the medieval world view, Nature was
conceived to be kept going from moment to moment by
a miracle which was always new and forever renewed. It
was God who ordered the universe through these
miracles. This entire scheme depended not only upon
God, but upon the individual's absolute and unwavering
faith in God. If God pronounced it to be so, then it must
be so. But after 1350, let's say, by the time of Petrarch
(1304-1374), some men became more interested in the
form of the miracle. Knowing that the cosmos was of
divine origin and moved according to the will of God,
some men embraced that Faustian spirit that wanted to
know more. It was not enough to simply accept the
existence of miracles -- the miracles now had to be
explained. These men wanted to know what order, to
what hierarchy the miracle conformed. And this brings
us to the medieval view of cosmological order.
According to the intellectual tradition stretching from
Aristotle to Dante, all things in nature -- all phenomena -
- are composed of four fundamental elements. These
elements were air, fire, earth and water. These
elements were believed to follow certain laws -- they
were to follow their ideal nature. So, since they are
heavy and coarse, water and earth move downward.
Likewise, since they are light and airy, air and fire move
upward. Each of the four elements is constantly striving
to reach its natural center. The striving of all these
elements is what kept the cosmos going. In this scheme
of things, the elements of air and fire predominated and
together they composed a fifth element, more pure
than the rest, which the ancients called "the aether."
And since the heavenly bodies are "up there," they
must be composed of "the aether." (The reader
interested in a succinct overview of cosmology should
consult the Foundations of Modern Cosmology page.)
Which brings me to relate a brief story. In 1666, and
with the city of London burning down, Isaac Newton left
his study at Cambridge and made his way to his
mother's home at Woolsthorpe in Lincolnshire. It was
here, in his mother's garden, that the great Newton was
struck by an idea -- the idea that the force which held
the planets in their orbit was the same force which
caused an apple to strike him in the head. Such an idea
-- we of course know it today as universal gravitation --
would have been absolutely unintelligible even to an
advanced medieval thinker. This is so for two reasons.
First, medieval man did not see the movement of the
heavenly bodies from the standpoint of the mechanics
of motion. The heavenly bodies, after all, were
composed entirely of aether. Theirs was an organic,
living world view rather than our now more familiar
mechanical conception. Second, and perhaps of even
more importance, medieval man could not understand
that the planets or the stars or comets were made of
the same stuff as an apple -- matter.
When it came to conceptualizing
the universe, the medieval world
borrowed its knowledge from the
Egyptian geographer and
astronomer Claudius Ptolemy
(c.90-c.168). The Ptolemaic
System put the stars on a fixed
sphere around the earth. At the
center was an object about which
nine concentric sphere were
situated. This object was the earth. Beyond the earth,
its position fixed, were the Moon, Sun, Mercury, Venus,
Mars, Jupiter, Saturn and then the stars, and finally, the
Prime Mover, the First Cause, God. The motions of the
planets were complicated. Ptolemy said the planets
moved in epicycles. The concept of epicycles was used
by Ptolemy to explain why planets seemed to exhibit
what is now known as retrograde motion, that is, the
tendency for planets to move in one direction, then
stop, change directions and then continue their original
movement. Ptolemy's system was accepted during the
Middle Ages but over time it became awkward. As
improvements were made in the skills of observation,
more and more epicycles were called for to explain the
movement of heavenly bodies. A simple, regular,
ordered and hierarchical system had, over time,
become very complicated. Criticism of the Ptolemaic
system began in the mid-16th century. The system
which eventually overthrew that of Ptolemy was not
based on criticism alone. Instead, another system took
its place -- and that system came with the emergence
of the New Science.
So monumental were
his achievements in
cosmology, the
Scientific Revolution
could almost have been
called the Copernican
Revolution. Born in
Poland in 1473, it was
the humble astronomer
Nicholas Copernicus
(1473-1543) who
challenged the
geocentrism of Ptolemy
with his own heliocentric universe. Ptolemy would never
recover -- neither would the Christian matrix.
Copernicus studied mathematics at Cracow and
managed to obtain a law degree from Bologna as well.
In 1500 he was in Rome where he witnessed a lunar
eclipse. The following year he studied medicine at
Padua and in 1505 he left Italy for Prussia. By 1512 he
was settled in Prussia where he not only observed the
movement of the heavenly bodies but also worked in
various capacities as a bailiff, military governor, judge,
tax collector, physician and reformer of the coinage. He
was an untypical man, an exceptional man, like one of
his contemporaries, Sir Thomas More, a Renaissance
man (see Lecture 1).
As we all know, it was Copernicus who determined that
the sun was at the center of the cosmos and that the
earth moved. Such an opinion alarmed his
contemporaries who could not explain that if the earth
were spinning then why was it that an arrow shot into
the air didn't fly off the face of the earth -- remember,
this is well before the idea of gravity had been
discovered by Newton. The Copernican system offended
the medieval sense that the universe was an affair
between God and man. Copernicus knew it too. The
ultimate authority, of course, was the Holy
Writ. That his contemporaries would be
alarmed by the heliocentric theory bothered
Copernicus. So, he decided to publish his
findings in 1543, the year of his death. It was
in that year that Copernicus published his
magnum opus, De revolutionibus orbium coelestium
(On the Revolutions of the Heavenly Bodies) at
Nuremberg. The book was dedicated to Pope Paul III.
Aware that he could not persuade the traditional
thinking of the time, Copernicus made a specific appeal
to mathematicians. It was, he thought, only the
mathematician who could understand and appreciate
the order and essential simplicity of his system. In the
DEDICATION to this most revolutionary of scientific
treatises, Copernicus wrote:
mathematics is written for mathematicians, to
whom these my labors, if I am not mistaken, will
appear to contribute something.
Copernicus never expected that his findings would
appeal to the non-specialist. But in 1572 something
happened. A new star appeared in the constellation of
Cassiopeia. The new star was observed by the Danish
astronomer, Tycho Brahe (1546-1601). The star was
brighter than any other star for more than two years --
contemporary accounts tell us that the star was so
bright that it could be seen in daylight. And in 1600,
another star appeared. This star was observed by
Johannes Kepler (1571-1630). The heavens seemed to
be in flux. Such occurrences made lasting impressions
on all men, whether scientist or not. After all, this was
an age in which men believed their fate to be written in
the stars and now those stars were changing. What
Brahe and Kepler had seen were super-novas, the
explosions of old stars.
Kepler, even more than Copernicus, was literally carried
away by the strange relationship between numbers and
the properties of the natural world. In his books,
Mysterium Cosmographicum (The Mysterious Universe,
1596) and Harmonice Mundi (The Harmonious World,
1619) one theme is presented repeatedly: "Nature loves
simplicity." From his friend Brahe, Kepler learned that it
was necessary to take more accurate measurements
while observing the movement of the heavenly bodies.
In the end, Kepler determined the three laws of
planetary motion, which he published between 1609
and 1619. (1) planets move in elliptical orbits. (2)
explained the varying speed of the planets and so,
retrograde motion, (3) relates the movement of one
planet to all the others. With the discovery of these
three laws within the framework of the heliocentric
universe, the paths of the planets were mapped forever.
All that remained would be to see these three laws as
part of a single unity -- a single law which held each
planet in its orbit about the sun. This of course, would
have to wait another seventy years -- this single law
would have to wait for the genius of Isaac Newton. But
what was needed before Newton could go to work was a
more practical and elaborate understanding of the
mechanics of motion (see Lecture 11).
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