Isaac Newton (The Obsessed Man )
Continual Thought:
In his later years, Isaac Newton was asked how he had arrived at his theory of
universal gravitation. “By thinking on it continually,” was his matter-of-fact re
sponse. “Continual thinking” for Newton was almost beyond mortal capacity. He
could abandon himself to his studies with a passion and ecstasy that others
experience in love affairs. The object of his study could become an obsession,
possessing him nonstop, and leaving him without food or sleep, beyond fatigue,
and on the edge of breakdown.
The world Newton inhabited in his ecstasy was vast. Richard Westfall, New
ton’s principal biographer in this century, describes this “world of thought”:
“Seen from afar, Newton’s intellectual life appears unimaginably rich. He em
braced nothing less than the whole of natural philosophy [science], which he
explored from several vantage points, ranging all the way from mathematical
physics to alchemy. Within natural philosophy, he gave new direction to optics,
mechanics, and celestial dynamics, and he invented the mathematical tool [cal
culus] that has enabled modern science further to explore the paths he first
blazed. He sought as well to plumb the mind of God and His eternal plan for the
world and humankind as it was presented in the biblical prophecies.”
But, after all, Newton was human. His passion for an investigation would fade,
and without synthesizing and publishing the work, he would move on to another
grand theme. “What he thought on, he thought on continually, which is to say
exclusively, or nearly exclusively,” Westfall continues, but “[his] career was ep
isodic.” To build a coherent whole, Newton sometimes revisited a topic several
times over a period of decades.
Woolsthorpe:
Newton was born on Christmas Day, 1642, at Woolsthorpe Manor, near the Lin
colnshire village of Colsterworth, sixty miles northwest of Cambridge and one hundred miles from London. Newton’s father, also named Isaac, died three
months before his son’s birth. The fatherless boy lived with his mother, Hannah,
for three years. In 1646, Hannah married Barnabas Smith, the elderly rector of
North Witham, and moved to the nearby rectory, leaving young Isaac behind at
Woolsthorpe to live with his maternal grandparents, James and Mary Ayscough.
Smith was prosperous by seventeenth-century standards, and he compensated
the Ayscoughs by paying for extensive repairs at Woolsthorpe.
Newton appears to have had little affection for his stepfather, his grandparents,
his half-sisters and half-brother, or even his mother. In a self-imposed confession
of sins, made after he left Woolsthorpe for Cambridge, he mentions “Peevishness
with my mother,” “with my sister,” “Punching my sister,” “Striking many,”
“Threatning my father and mother Smith to burne them and the house over
them,” “wishing death and hoping it to some.”
In 1653, Barnabas Smith died, Hannah returned to Woolsthorpe with the three
Smith children, and two years later Isaac entered grammar school in Grantham,
about seven miles from Woolsthorpe. In Grantham, Newton’s genius began to
emerge, but not at first in the classroom. In modern schools, scientific talent is
often first glimpsed as an outstanding aptitude in mathematics. Newton did not
have that opportunity; the standard English grammar school curriculum of the
time offered practically no mathematics. Instead, he displayed astonishing me
chanical ingenuity. William Stukely, Newton’s first biographer, tells us that he
quickly grasped the construction of a windmill and built a working model,
equipped with an alternate power source, a mouse on a treadmill. He constructed
a cart that he could drive by turning a crank. He made lanterns from “crimpled
paper” and attached them to the tails of kites. According to Stukely, this stunt
“Wonderfully affrighted all the neighboring inhabitants for some time, and caus’d
not a little discourse on market days, among the country people, when over their
mugs of ale.”
Another important extracurricular interest was the shop of the local apothe
cary, remembered only as “Mr. Clark.” Newton boarded with the Clark family,
and the shop became familiar territory. The wonder of the bottles of chemicals
on the shelves and the accompanying medicinal formulations would help direct
him to later interests in chemistry, and beyond that to alchemy.
With the completion of the ordinary grammar school course of studies, New
ton reached a crossroads. Hannah felt that he should follow in his father’s foot
steps and manage the Woolsthorpe estate. For that he needed no further educa
tion, she insisted, and called him home. Newton’s intellectual promise had been
noticed, however. Hannah’s brother, William Ayscough, who had attended Cam
bridge, and the Grantham schoolmaster, John Stokes, both spoke persuasively on
Newton’s behalf, and Hannah relented. After nine months at home with her rest
less son, Hannah no doubt recognized his ineptitude for farm management. It
probably helped also that Stokes was willing to waive further payment of the
forty-shilling fee usually charged for nonresidents of Grantham. Having passed
this crisis, Newton returned in 1660 to Grantham and prepared for Cambridge.
Cambridge:
Newton entered Trinity College, Cambridge, in June 1661, as a “subsizar,” mean
ing that he received free board and tuition in exchange for menial service. In the
Cambridge social hierarchy, sizars and subsizars were on the lowest level. Ev dently Hannah Smith could have afforded better for her son, but for some reason
(possibly parsimony) chose not to make the expenditure.
With his lowly status as a subsizar, and an already well developed tendency
to introversion, Newton avoided his fellow students, his tutor, and most of the
Cambridge curriculum (centered largely on Aristotle). Probably with few regrets,
he went his own way. He began to chart his intellectual course in a “Philosoph
ical Notebook,” which contained a section with the Latin title Quaestiones quae
dam philosophicam (Certain Philosophical Questions) in which he listed and
discussed the many topics that appealed to his unbounded curiosity. Some of
the entries were trivial, but others, notably those under the headings “Motion”
and “Colors,” were lengthy and the genesis of later major studies.
After about a year at Cambridge, Newton entered, almost for the first time, the
f
ield of mathematics, as usual following his own course of study. He soon trav
eled far enough into the world of seventeenth-century mathematical analysis to
initiate his own explorations. These early studies would soon lead him to a geo
metrical demonstration of the fundamental theorem of calculus.
Beginning in the summer of 1665, life in Cambridge and in many other parts
of England was shattered by the arrival of a ghastly visitor, the bubonic plague.
For about two years the colleges were closed. Newton returned to Woolsthorpe,
and took with him the many insights in mathematics and natural philosophythat
had been rapidly unfolding in his mind.
Newton must have been the only person in England to recall the plague years
1665–66 with any degree of fondness. About fifty years later he wrote that “in
those days I was in the prime of my age for invention & minded Mathematicks
& Philosophy more then than at any time since.” During these “miracle years,”
as they were later called, he began to think about the method of fluxions (his
version of calculus), the theory of colors, and gravitation. Several times in his
later years Newton told visitors that the idea of universal gravitation came to him
when he saw an apple fall in the garden at Woolsthorpe; if gravity brought the
apple down, he thought, why couldn’t it reach higher, as high as the Moon?
These ideas were still fragmentary, but profound nevertheless. Later they
would be built into the foundations of Newton’s most important work. “The mir
acle,” says Westfall, “lay in the incredible program of study undertaken in private
and prosecuted alone by a young man who thereby assimilated the achievement
of a century and placed himself at the forefront of European mathematics and
science.”
Genius of this magnitude demands, but does not always receive, recognition.
Newton was providentially lucky. After graduation with a bachelor’s degree, the
only way he could remain at Cambridge and continue his studies was to be
elected a fellow of Trinity College. Prospects were dim. Trinity had not elected
fellows for three years, only nine places were to be filled, and there were many
candidates. Newton was not helped by his previous subsizar status and unortho
dox program of studies. But against all odds, he was included among the elected.
Evidently he had a patron, probably Humphrey Babington, who was related to
Clark, the apothecary in Grantham, and a senior fellow of Trinity.
The next year after election as a “minor” fellow, Newton was awarded the
Master of Arts degree and elected a “major” fellow. Then in 1668, at age twenty
seven and still insignificant in the college, university, and scientific hierarchy,
he was appointed Lucasian Professor of Mathematics. His patron for this sur
prising promotion was Isaac Barrow, who was retiring from the Lucasian chair and expecting a more influential appointment outside the university. Barrow had
seen enough of Newton’s work to recognize his brilliance.
Newton’s Trinity fellowship had a requirement that brought him to another
serious crisis. To keep his fellowship he regularly had to affirm his belief in the
articles of the Anglican Church, and ultimately be ordained a clergyman. Newton
met the requirement several times, but by 1675, when he could no longer escape
the ordination rule, his theological views had taken a turn toward heterodoxy,
even heresy. In the 1670s Newton immersed himself in theological studies that
eventually led him to reject the doctrine of the Trinity. This was heresy, and if
admitted, meant the ruination of his career. Although Newton kept his heretical
views secret, ordination was no longer a possibility, and for a time, his Trinity
fellowship and future at Cambridge appeared doomed.
But providence intervened, once again in the form of Isaac Barrow. Since leav
ing Cambridge, Barrow had served as royal chaplain. He had the connections at
Court to arrange a royal dispensation exempting the Lucasian Professor from the
ordination requirement, and another chapter in Newton’s life had a happy
ending.
Critics:
Newton could not stand criticism, and he had many critics. The most prominent
and influential of these were Robert Hooke in England, and Christiaan Huygens
and Gottfried Leibniz on the Continent.
Hooke has never been popular with Newton partisans. One of his contempo
raries described him as “the most ill-natured, conceited man in the world, hated
and despised by most of the Royal Society, pretending to have all other inven
tions when once discovered by their authors.” There is a grain of truth in this
concerning Hooke’s character, but he deserves better. In science he made contri
butions to optics, mechanics, and even geology. His skill as an inventor was
renowned, and he was a surveyor and an architect. In personality, Hooke and
Newton were polar opposites. Hooke was a gregarious extrovert, while Newton,
at least during his most creative years, was a secretive introvert. Hooke did not
hesitate to rush into print any ideas that seemed plausible. Newton shaped his
concepts by thinking about them for years, or even decades. Neither man could
bear to acknowledge any influence from the other. When their interests over
lapped, bitter confrontations were inevitable.
Among seventeenth-century physicists, Huygens was most nearly Newton’s
equal. He made important contributions in mathematics. He invented the pen
dulum clock and developed the use of springs as clock regulators. He studied
telescopes and microscopes and introduced improvements in their design. His
studies in mechanics touched on statics, hydrostatics, elastic collisions,projectile
motion, pendulum theory, gravity theory, and an implicit force concept, includ
ing the concept of centrifugal force. He pictured light as a train of wave fronts
transmitted through a medium consisting of elastic particles. In matters relating
to physics, this intellectual menu is strikingly similar to that of Newton. Yet
Huygens’s influence beyond his own century was slight, while Newton’s was
enormous. One of Huygens’s limitations was that he worked alone and had few
disciples. Also, like Newton, he often hesitated to publish, and when the work
f
inally saw print others had covered the same ground. Most important, however,
was his philosophical bias. He followed Rene´ Descartes in the belief that natural phenomena must have mechanistic explanations. He rejected Newton’s theory of
universal gravitation, calling it “absurd,” because it was no more than mathe
matics and proposed no mechanisms.
Leibniz, the second of Newton’s principal critics on the Continent, is re
membered more as a mathematician than as a physicist. Like that of Huygens,
his physics was limited by a mechanistic philosophy. In mathematics he made
two major contributions, an independent (after Newton’s) invention of calculus,
and an early development of the principles of symbolic logic. One manifestation
of Leibniz’s calculus can be seen today in countless mathematics and physics
textbooks: his notation. The basic operations of calculus are differentiation and
integration, accomplished with derivatives and integrals. The Leibniz symbols
dy
dx
for derivatives (e.g., ) and integrals (e.g., ∫ydx) have been in constant use for
more than three hundred years. Unlike many of his scientific colleagues, Leibniz
never held an academic post. He was everything but an academic, a lawyer,
statesman, diplomat, and professional genealogist, with assignments such as ar
ranging peace negotiations, tracing royal pedigrees, and mapping legal reforms.
Leibniz and Newton later engaged in a sordid clash over who invented calculus
first.
Calculus Lessons :
The natural world is in continuous, never-ending flux. The aim of calculus is to
describe this continuous change mathematically. As modern physicists see it, the
methods of calculus solve two related problems. Given an equation thatexpresses
a continuous change, what is the equation for the rate of the change? And, con
versely, given the equation for the rate of change, what is the equation for the
change? Newton approached calculus this way, but often with geometrical ar
guments that are frustratingly difficult for those with little geometry. I will avoid
Newton’s complicated constructions and present here for future reference a few
rudimentary calculus lessons more in the modern style.
Suppose you want to describe the motion of a ball falling freely from the Tower
in Pisa. Here the continuous change of interest is the trajectory of the ball, ex
pressed in the equation
.......(1)
in which t represents time, s the ball’s distance from the top of the tower, and g
a constant we will interpret later as the gravitational acceleration. One of the
problems of calculus is to begin with equation (1) and calculate the ball’s rate of
fall at every instant.
This calculation is easily expressed in Leibniz symbols. Imagine that the ball
is located a distance s from the top of the tower at time t, and that an instant
later, at time t
dt, it is located at s ds; the two intervals dt and ds, called
“differentials” in the terminology of calculus, are comparatively very small. We
have equation (1) for time t at the beginning of the instant. Now write the equa
tion for time t dt at the end of the instant, with the ball at s ds,
......(2)
Notice the term s on the left side of the last equation and the term the right.
2
According to equation (1), these terms are equal, so they can be canceled from
the last equation, leaving
......(3)
tion (5) for the rate of the change at any instant. Calculus also supplies the means
Optics:
The work that first brought Newton to the attention of the scientific community
was not a theoretical or even a mathematical effort; it was a prodigious technical
achievement. In 1668, shortly before his appointment as Lucasian Professor,
Newton designed and constructed a “reflecting” telescope. In previous tele
scopes, beginning with the Dutch invention and Galileo’s improvement, lightwas
refracted and focused by lenses. Newton’s telescope reflected and focused light
with a concave mirror. Refracting telescopes had limited resolution and to
achieve high magnification had to be inconveniently long. (Some refracting tele
scopes at the time were a hundred feet long, and a thousand-footer was planned.)
Newton’s design was a considerable improvement on both counts.
Newton’s telescope project was even more impressive than that of Galileo.
With no assistance (Galileo employed a talented instrument maker), Newton cast
and ground the mirror, using a copper alloy he had prepared, polished the mirror,
and built the tube, the mount, and the fittings. The finished product was just six
inches in length and had a magnification of forty, equivalent to a refracting tele
scope six feet long.
Newton was not the first to describe a reflecting telescope. James Gregory,
professor of mathematics at St. Andrews University in Scotland, had earlier pub
lished a design similar to Newton’s, but could not find craftsmen skilled enough
to construct it.
Noless than Galileo’s, Newton’s telescope was vastly admired. In 1671,Barrow demonstrated it to the London gathering of prominent natural philosophers
known as the Royal Society. The secretary of the society, Henry Oldenburg,wrote
to Newton that his telescope had been “examined here by some of the most
eminent in optical science and practice, and applauded by them.” Newton was
promptly elected a fellow of the Royal Society.
Before the reflecting telescope, Newton had made other major contributions in
the field of optics. In the mid-1660s he had conceived a theory that held that
ordinarywhitelightwasamixtureofpurecolorsrangingfromred,throughorange,
yellow, green, and blue, to violet, the rainbow of colors displayed by a prism
when it receives a beam of white light. In Newton’s view, the prism separated
the pure components by refracting each to a different extent. This was a contra
diction of the prevailing theory, advocated by Hooke, among others, that light in
the purest form is white, and colors are modifications of the pristine white light.
Newton demonstrated the premises of his theory in an experiment employing
two prisms. The first prism separated sunlight into the usual red-through-violet
components, and all of these colors but one were blocked in the beam received
by the second prism. The crucial observation was that the second prism caused
no further modification of the light. “The purely red rays refracted by the second
prism made no other colours but red,” Newton observed in 1666, “& the purely
blue no other colours but blue ones.” Red and blue, and other colors produced
by the prism, were the pure colors, not the white.
Soon after his sensational success with the reflecting telescope in 1671, New
ton sent a paper to Oldenburg expounding this theory. The paper was read at a
meeting of the Royal Society, to an enthusiastically favorable response. Newton
was then still unknown as a scientist, so Oldenburg innocently took the addi
tional step of asking Robert Hooke, whose manifold interests included optics, to
comment on Newton’s theory. Hooke gave the innovative and complicated paper
about three hours of his time, and told Oldenburg that Newton’s arguments were
not convincing.
This responsetouchedoffthefirstofNewton’spolemicalbattleswithhiscritics.
His first reply was restrained; it prompted Hooke to give the paper in question
more scrutiny, and to focus on Newton’s hypothesis that light is particle-like.
(Hooke had found an inconsistency here; Newton claimed that he did not rely on
hypotheses.) Newton was silent for awhile, and Hooke, never silent, claimed that
he had built a reflecting telescope before Newton. Next, Huygens and a Jesuit
priest, Gaston Pardies, entered the controversy. Apparently in support of Newton,
Huygens wrote, “The theory of Mr. Newton concerning light and colors appears
highly ingenious to me.” In a communicationtothePhilosophicalTransactionsof
the Royal Society, Pardies questioned Newton’s prism experiment, and Newton’s
reply, which also appeared in the Transactions, was condescending. Hooke com
plained to Oldenburg that Newton was demeaning the debate, and Oldenburg
wrote a cautionary letter to Newton. By this time, Newton was aroused enough to
refute all of Hooke’s objections in a lengthy letter to the Royal Society, later pub
lished in the Transactions. This did not quite close the dispute; in a final episode,
Huygens reentered the debate with criticisms similar to those offered by Hooke.
In too many ways, this stalemate between Newton and his critics was petty,
but it turned finally on an important point. Newton’s argument relied crucially
on experimental evidence; Hooke and Huygens would not grant the weight of
that evidence. This was just the lesson Galileo had hoped to teach earlier in the
century. Now it was Newton’s turn.
Alchemyand Heresy:
In his nineteenth-century biography of Newton, David Brewster surprised his
readers with an astonishing discovery. He revealed for the first time that Newton’s
papers included a vast collection of books, manuscripts, laboratory notebooks,
recipes, and copied material on alchemy. How could “a mind of such power...
stoop to be even the copyist of the most contemptible alchemical poetry,” Brew
ster asked. Beyond that he had little more to say about Newton the alchemist.
By the time Brewster wrote his biography, alchemy was a dead and unla
mented endeavor, and the modern discipline of chemistry was moving forward
at a rapid pace. In Newton’s century the rift between alchemy and chemistry was
just beginning to open, and in the previous century alchemy was chemistry.
Alchemists, like today’s chemists, studied conversions of substances into other
substances, and prescribed the rules and recipes that governed the changes. The
ultimate conversion for the alchemists was the transmutation of metals,including
the infamous transmutation of lead into gold. The theory of transmutation had
many variations and refinements, but a fundamental part of the doctrine was the
belief that metals are compounded of mercury and sulfur—not ordinary mercury
and sulfur but principles extracted from them, a “spirit of sulfur” and a “philo
sophic mercury.” The alchemist’s goal was to extract these principles from im
pure natural mercury and sulfur; once in hand, the pure forms could be com
bined to achieve the desired transmutations. In the seventeenth century, this
program was still plausible enough to attract practitioners, and the practitioners
patrons, including kings.
The alchemical literature was formidable. There were hundreds of books
(Newton had 138 of them in his library), and they were full of the bizarre ter
minology and cryptic instructions alchemists devised to protect their work from
competitors. But Newton was convinced that with thorough and discriminating
study, coupled with experimentation, he could mine a vein of reliable observa
tions beneath all the pretense and subterfuge. So, in about 1669, he plunged into
the world of alchemy, immediately enjoying the challenges of systematizing the
chaotic alchemical literature and mastering the laboratory skills demanded by
the alchemist’s fussy recipes.
Newton’s passion for alchemy lasted for almost thiry years. He accumulated
more than a million words of manuscript material. An assistant, HumphreyNew
ton (no relation), reported that in the laboratory the alchemical experiments gave
Newton “a great deal of satisfaction & Delight....TheFire [in the laboratory
furnaces] scarcely going out either Night or Day....HisPains, his Dilligence at
those sett times, made me think, he aim’d at something beyond ye Reach of
humane Art & Industry.”
What did Newton learn during his years in company with the alchemists? His
transmutation experiments did not succeed, but he did come to appreciate a
fundamental lesson still taught by modern chemistry and physical chemistry:
that the particles of chemical substances are affected by the forces of attraction
and repulsion. He saw in some chemical phenomena a “principle of sociability”
and in others “an endeavor to recede.” This was, as Westfall writes, “arguably
the most advanced product of seventeenth-century chemistry.” It presaged the
modern theory of “chemical affinities,” which will be addressed in chapter 10.
For Newton, the attraction forces he saw in his crucibles were of a piece with
the gravitational force. There is no evidence that he equated the two kinds offorces, but some commentators have speculated that his concept of universal
gravitation was inspired, not by a Lincolnshire apple, but by the much more
complicated lessons of alchemy.
During the 1670s, Newton had another subject for continual study and
thought; he was concerned with biblical texts instead of scientific texts. He be
came convinced that the early Scriptures expressed the Unitarian belief that al
though Christ was to be worshipped, he was subordinate to God. Newton cited
historical evidence that this text was corrupted in the fourth century by the in
troduction of the doctrine of the Trinity. Any form of anti-Trinitarianism was
considered heresy in the seventeenth century. To save his fellowship at Cam
bridge, Newton kept his unorthodox beliefs secret, and, as noted, he was rescued
by a special dispensation when he could no longer avoid the ordination require
ment of the fellowship.
Halley’s Question :
In the fall of 1684, Edmond Halley, an accomplished astronomer, traveled to
Cambridge with a question for Newton. Halley had concluded that the gravita
tional force between the Sun and the planets followed an inverse-square law—
that is, the connection between this “centripetal force” (as Newton later called
it) and the distance r between the centers of the planet and the Sun is
(Read “proportional to” for the symbol .) The force decreases by 1⁄22 1⁄4 if r
doubles, by 1⁄32 1⁄9 if r triples, and so forth. Halley’s visit and his question were
later described by a Newton disciple, Abraham DeMoivre:
In 1684 Dr Halley came to visit [Newton] at Cambridge, after they had some
time together, the Dr asked him what he thought the curve would be that would
be described by the Planets supposing the force of attraction towards the Sun
to be reciprocal to the square of their distance from it. Sr Isaac replied imme
diately that it would be an [ellipse], the Doctor struck with joy & amazement
asked him how he knew it, why saith he I have calculated it, whereupon Dr
Halley asked him for his calculation without farther delay, Sr Isaac looked
among his papers but could not find it, but he promised him to renew it, & then
send it to him.
A few months later Halley received the promised paper, a short, but remark
able, treatise, with the title De motu corporum in gyrum (On the Motion of Bodies
in Orbit). It not only answered Halley’s question, but also sketched a new system
of celestial mechanics, a theoretical basis for Kepler’s three laws of planetary
Kepler’s Laws:
Johannes Kepler belonged to Galileo’s generation, although the two never met.
In 1600, Kepler became an assistant to the great Danish astronomer Tycho Brahe,
An elliptical planetaryorbit. The orbit shown is
exaggerated. Most planetaryorbits are nearlycircular.
and on Tycho’s death, inherited both his job and his vast store of astronomical
observations. From Tycho’s data Kepler distilled three great empirical laws:
1. The Law of Orbits: The planets move in elliptical orbits, with the Sun situ
ated at one focus.
Figure 2.1 displays the geometry of a planetary ellipse. Note the dimensions a
and b of the semimajor and semiminor axes, and the Sun located at one focus.
2. The Law of Equal Areas: A line joining any planet to the Sun sweeps out
equal areas in equal times.
Figure 2.2 illustrates this law, showing the radial lines joining a planet with the
Sun, and areas swept out by the lines in equal times with the planet traveling
different parts of its elliptical orbit. The two areas are equal, and the planet
travels faster when it is closer to the Sun.
3. The Law of Periods: The square of the period of any planet about the Sun is
proportional to the cube of the length of the semimajor axis.
A planet’s period is the time it requires to travel its entire orbit—365 days for
Earth. Stated as a proportionality, with P representing the period and a the length
of the semimajor axis, this law asserts that
Halley’s Reward:
“I keep [a] subject constantly before me,” Newton once remarked, “and wait ’till
the first dawnings open slowly, by little and little, into a full and clear light.”
Kepler’s laws had been on Newton’s mind since his student days. In “first dawn
ings” he had found connections between the inverse-square force law and Ke
pler’s first and third laws, and now in De motu he was glimpsing in “a full and
clear light” the entire theoretical edifice that supported Kepler’s laws and other
astronomical observations. Once more, Newton’s work was “the passionate study
of a man obsessed.” His principal theme was the mathematical theory of univer
sal gravitation.
First, he revised and expanded De motu, still focusing on celestial mechanics,
and then aimed for a grander goal, a general dynamics, including terrestrial as
well as celestial phenomena. This went well beyond De motu, even in title. For
the final work, Newton chose the Latin title Philosophiae naturalis principia
mathematica (Mathematical Principles of Natural Philosophy), usually shortened
to the Principia.
When it finally emerged, the Principia comprised an introduction and three
books. The introduction contains definitions and Newton’s candidates for the
fundamental laws of motion. From these foundations, book 1 constructs exten
sive and sophisticated mathematical equipment, and applies it to objects moving
without resistance—for example, in a vacuum. Book 2 treats motion in resisting
mediums—for example, in a liquid. And book 3 presents Newton’s cosmology,
his “system of the world.”
In a sense, Halley deserves as much credit for bringing the Principia into the
world as Newton does. His initial Cambridge visit reminded Newton of unfin
ished business in celestial mechanics and prompted the writing of De motu.
When Halley saw De motu in November 1684, he recognized it for what it was,
the beginning of a revolution in the science of mechanics. Without wasting any
time, he returned to Cambridge with more encouragement. None was needed.
Newton was now in full pursuit of the new dynamics. “From August 1684 until
the spring of 1686,” Westfall writes, “[Newton’s] life [was] a virtual blank except
for the Principia.”
By April 1686, books 1 and 2 were completed, and Halley began a campaign
for their publication by the Royal Society. Somehow (possibly with Halley ex
ceeding his limited authority as clerk of the society), the members were per
suaded at a general meeting and a resolution was passed, ordering “that Mr.
Newton’s Philosophiae naturalis principia mathematica be printed forthwith.”
Halley was placed in charge of the publication.
Halley now had the Principia on the road to publication, but it was to be a
bumpy ride. First, Hooke made trouble. He believed that he had discovered the
inverse-square law of gravitation and wanted recognition from Newton. The ac
knowledgment, if any, would appear in book 3, now nearing completion.Newton
refused to recognize Hooke’s priority, and threatened to suppress book 3. Halley
had not yet seen book 3, but he sensed that without it the Principia would be a
body without a head. “Sr I must now again beg you, not to let your resentment
run so high, as to deprive us of your third book,” he wrote to Newton. The
beheading was averted, and Halley’s diplomatic appeals may have been the de
cisive factor.
In addition to his editorial duties, Halley was also called upon to subsidize the publication of the Principia. The Royal Society was close to bankruptcy and
unable even to pay Halley his clerk’s salary of fifty pounds. In his youth, Halley
had been wealthy, but by the 1680s he was supporting a family and his means
were reduced. The Principia was a gamble, and it carried some heavy financial
risks.
But finally, on July 5, 1687, Halley could write to Newton and announce that
“I have at length brought your Book to an end.” The first edition sold out quickly.
Halley at least recovered his costs, and more important, he received the acknow
ledgment from Newton that he deserved: “In the publication of this work the
most acute and universally learned Mr Edmund Halley not only assisted me in
correcting the errors of the press and preparing the geometrical figures, but it
was through his solicitations that it came to be published.”
The Principia :
What Halley coaxed from Newton is one of the greatest masterpieces in scientific
literature. It is also one of the most inaccessible books ever written. Arguments
in the Principia are presented formally as propositions with (sometimes sketchy)
demonstrations. Some propositions are theorems and others are developed as
illustrative calculations called “problems.” The reader must meet the challenge
of each proposition in sequence to grasp the full argument.
Modern readers of the Principia are also burdened by Newton’s singular math
ematical style. Propositions are stated and demonstrated in the language of geo
metry, usually with reference to a figure. (In about five hundred pages, the Prin
cipia has 340 figures, some of them extremely complicated.) To us this seems an
anachronism. By the 1680s, when the Principia was under way, Newton had
already developed his fluxional method of calculus. Why did he not use calculus
to express his dynamics, as we do today?
Partly it was an aesthetic choice. Newton preferred the geometry of the “an
cients,” particularly Euclid and Appolonius, to the recently introduced algebra
of Descartes, which played an essential role in fluxional equations. He found the
geometrical method “much more elegant than that of Descartes...[who] attains
the result by means of an algebraic calculus which, if one transcribed it in words
(in accordance with the practice of the Ancients in their writings) is revealed
to be boring and complicated to the point of provoking nausea, and not be
understood.”
There was another problem. Newton could not use the fluxion language he
had invented twenty years earlier for the practical reason that he had never pub
lished the work (and would not publish it for still another twenty years). As the
science historian Franc ¸ois De Gandt explains, “[The] innovative character [of the
Principia] was sure to excite controversy. To combine with this innovative char
acter another novelty, this time mathematical, and to make unpublished proce
dures in mathematics the foundation for astonishing physical assertions, was to
risk gaining nothing.”
So Newton wrote the Principia in the ancient geometrical style, modifiedwhen
necessary to represent continuous change. But he did not reach his audience.
Only a few of Newton’s contemporaries read the Principia with comprehension,
and following generations chose to translate it into a more transparent, if less
elegant, combination of algebra and the Newton-Leibniz calculus. The fate of the
Principia, like that of some of the other masterpieces of scientific literature (Clausius on thermodynamics, Maxwell on the electromagnetic field, Boltzmann
on gas theory, Gibbs on thermodynamics, and Einstein on general relativity), was
to be more admired than read.
The fearsome challenge of the Principia lies in its detailed arguments. In out
line, free of the complicated geometry and the maddening figures, the work is
muchmoreaccessible. It begins with definitions of two of the most basicconcepts
of mechanics:
Definition 1: The quantity of matter is the measure of the same arising from its
density and bulk conjointly.
Definition 2: The quantity of motion is the measure of the same, arising from
the velocity and quantity of matter conjointly.
By “quantity of matter” Newton means what we call “mass,” “quantityofmotion”
in our terms is “momentum,” “bulk” can be measured as a volume, and“density”
is the mass per unit volume (lead is more dense than water, and water more
dense than air). Translated into algebraic language, the two definitions read
The first two laws convey simple physical messages. Imagine that your car is
coasting on a flat road with the engine turned off. If the car meets no resistance
(for example, in the form of frictional effects), Newton’s first law tells us that the
car will continue coasting with its original momentum and direction forever.
With the engine turned on, and your foot on the accelerator, the car is driven by
the engine’s force, and Newton’s second law asserts that the momentum increases
dp
dt
at a rate ( )equaltotheforce.Inother words: increase the forcebydepressing
the accelerator and the car’s momentum increases.
Newton’s third law asserts a necessary constraint on forces operating mutually
between two bodies:
Law 3: To every action there is always opposed an equal reaction: or, the mutual
actions of two bodies upon each other are always equal, and directed to con
trary parts.
Newton’s homely example reminds us, “If you press on a stone with your finger,
the finger is also pressed by the stone.” If this were not the case, the stone would
be soft and not stonelike.
Building from this simple, comprehensible beginning, Newton takes us on a
grand tour of terrestrial and celestial dynamics. In book 1 he assumes an inverse
square centripetal force and derives Kepler’s three laws. Along the way (in prop
osition 41), a broad concept that we now recognize as conservation of mechanical
energy emerges, although Newton does not use the term “energy,” and does not
emphasize the conservation theme.
Book 1 describes the motion of bodies (for example, planets) moving without
resistance. In book 2, Newton approaches the more complicated problem of mo
tion in a resisting medium. This book was something of an afterthought, origi
nally intended as part of book 1. It is more specialized than the other two books,
and less important in Newton’s grand scheme.
Book 3 brings the Principia to its climax. Here Newton builds his “system of
the world,” based on the three laws of motion, the mathematical methods de
veloped earlier, mostly in book 1, and empirical raw material available in astro
nomical observations of the planets and their moons.
The first three propositions put the planets and their moons in elliptical orbits
controlled by inverse-square centripetal forces, with the planets orbiting the Sun,
and the moons their respective planets. These propositions define the centripetal
forces mathematically but have nothing to say about their physical nature.
Proposition 4 takes that crucial step. It asserts “that the Moon gravitates to
wards the earth, and is always drawn from rectilinear [straight] motion, and held
back in its orbit, by the force of gravity.” By the “force of gravity” Newton means
the force that causes a rock (or apple) to fall on Earth. The proposition tells us
that the Moon is a rock and that it, too, responds to the force of gravity.
Newton’s demonstration of proposition 4 is a marvel of simplicity. First, from
the observed dimensions of the Moon’s orbit he concludes that to stay in its orbit
the Moon falls toward Earth 15.009 “Paris feet” ( 16.000 of our feet) every second. Then, drawing on accurate pendulum data observed by Huygens, he
calculates that the number of feet the Moon (or anything else) would fall in one
second on the surface of Earth is 15.10 Paris feet. The two results are close
enough to each other to demonstrate the proposition.
Proposition 5 simply assumes that what is true for Earth and the Moon is true
for Jupiter and Saturn and their moons, and for the Sun and its planets.
Finally, in the next two propositions Newton enunciates his universal law of
gravitation. I will omit some subtleties and details here and go straight to the
algebraic equation that is equivalent to Newton’s inverse-square calculation of
the gravitational attraction force F between two objects whose masses are m1 and
m2
where r is the distance separating the centers of the two objects, and G, called
the “gravitational constant,” is a universal constant. With a few exceptions, in
volving such bizarre objects as neutron stars and black holes, this equation ap
plies to any two objects in the universe: planets, moons, comets, stars, and gal
axies. The gravitational constant G is always given the same value; it is the
hallmark of gravity theory. Later in our story, it will be joined by a few other
universal constants, each with its own unique place in a major theory.
In the remaining propositions of book 3, Newton turns to more-detailed prob
lems. He calculates the shape of Earth (the diameter at the equator is slightly
larger than that at the poles), develops a theory of the tides, and shows how to
use pendulum data to demonstrate variations in weight at different points on
Earth. He also attempts to calculate the complexities of the Moon’s orbit, but is
not completely successful because his dynamics has an inescapable limitation:
it easily treats the mutual interaction (gravitational or otherwise) of two bodies,
but offers no exact solution to the problem of three or more bodies. The Moon’s
orbit is largely, but not entirely, determined by the Earth-Moon gravitational at
traction. The full calculation is a “three-body” problem, including the slight ef
fect of the Sun. In book 3, Newton develops an approximate method of calcula
tion in which the Earth-Moon problem is first solved exactly and is then modified
by including the “perturbing” effect of the Sun. The strategy is one of successive
approximations. The calculations dictated by this “perturbation theory” are te
dious, and Newton failed to carry them far enough to obtain good accuracy. He
complained that the prospect of carrying the calculations to higher accuracy
“made his head ache.”
Publication of the Principia brought more attention to Newton than to his
book. There were only a few reviews, mostly anonymous and superficial. As De
Gandt writes, “Philosophers and humanists of this era and later generations had
the feeling that great marvels were contained in these pages; they were told that
Newton revealed truth, and they believed it....ButthePrincipia still remained a sealed book.
The Opticks:
Newton as a young man skirmished with Hooke and others on the theory of
colors and other aspects of optics. These polemics finally drove him into a silence of almost thirty years on the subject of optics, with the excuse that he did not
want to be “engaged in Disputes about these Matters.” What persuaded him to
break the silence and publish more of his earlier work on optics, as well as some
remarkable speculations, may have been the death of his chief adversary, Hooke,
in 1703. In any case, Newton published his other masterpiece, the Opticks, in
1704.
The Opticks and the Principia are contrasting companion pieces. The two
books have different personalities, and may indeed reflect Newton’s changing
persona. The Principia was written in the academic seclusion of Cambridge, and
the Opticks in the social and political environment Newton entered after moving
to London. The Opticks is a more accessible book than the Principia. It is written
in English, rather than in Latin, and does not burden the reader with difficult
mathematical arguments. Not surprisingly, Newton’s successors frequently men
tioned the Opticks, but rarely the Principia.
In the Opticks, Newton presents both the experimental foundations, and an
attempt to lay the theoretical foundations, of the science of optics. He describes
experiments that demonstrate the main physical properties of light rays: their
reflection, “degree of refrangibility” (the extent to which they are refracted), “in
f
lexion” (diffraction), and interference.
The term “interference” was not in Newton’s vocabulary, but he describes
interference effects in what are now called “Newton’s rings.” In the demonstra
tion experiment, two slightly convex prisms are pressed together, with a thin
layer of air between them; a striking pattern of colored concentric rings appears,
surrounding points where the prisms touch.
Diffraction effects are demonstrated by admitting into a room a narrow beam
of sunlight through a pinhole and observing that shadows cast by this light source
on a screen have “Parallel Fringes or Bands of colour’d Light” at their edges.
To explain this catalogue of optical effects, Newton presents in the Opticks a
theory based on the concept that light rays are the trajectories of small particles.
As he puts it in one of the “queries” that conclude the Opticks: “Are not the
Rays of Light very small Bodies emitted from shining Substances? For such Bod
ies will pass through Mediums in right Lines without bending into the Shadow,
which is the Nature of the Rays of Light.”
In another query, Newton speculates that particles of light are affected by op
tical forces of some kind: “Do not Bodies act upon Light at a distance, and by
their action bend its Rays; and is not this action strongest at the least distance?”
With particles and forces as the basic ingredients, Newton constructs in the
Opticks an optical mechanics, which he had already sketched at the end of book
1 of the Principia. He explains reflection and refraction by assuming that optical
forces are different in different media, and diffraction by assuming that light rays
passing near an object are more strongly affected by the forces than those more
remote.
To explain the rings, Newton introduces his theory of “fits,” based on the idea
that light rays alternate between “Fits of easy Reflexion, and...Fits of easy
Transmission.” In this way, he gives the rays periodicity, that is, wavelike char
acter. However, he does not abandon the particle point of view, and thus arrives
at a complicated duality.
We now understand Newton’s rings as an interference phenomenon, arising
when two trains of waves meet each other. This theory was proposed by Thomas
Young, one of the first to see the advantages of a simple wave theory of light,
almost a century after the Opticks was published. By the 1830s, Young inEngland
and Augustin Fresnel in France had demonstrated that all of the physical prop
erties of light known at the time could be explained easily by a wave theory.
Newton’s particle theory of light did not survive this blow. For seventy-five
years the particles were forgotten, until 1905, when, to everyone’s astonishment,
Albert Einstein brought them back. (But we are getting about two centuries be
yond Newton’s story. I will postpone until later [chapter 19] an extended excur
sion into the strange world of light waves and particles.)
The queries that close the Opticks show us where Newton finally stood on
two great physical concepts. In queries 17 through 24, he leaves us with a picture
of the universal medium called the “ether,” which transmits optical and gravi
tational forces, carries light rays, and transports heat. Query 18 asks, “Is not this
medium exceedingly more rare and subtile than the Air, and exceedingly more
elastick and active? And doth not it readily pervade all Bodies? And is it not (by
its elastick force) expanded through all the Heavens?” The ether concept in one
form or another appealed to theoreticians through the eighteenth and nineteenth
centuries. It met its demise in 1905, that fateful year when Einstein not only
resurrected particles of light but also showed that the ether concept was simply
unnecessary.
In query 31, Newton closes the Opticks with speculations on atomism, which
he sees (and so do we) as one of the grandest of the unifying concepts in physics.
He places atoms in the realm of another grand concept, that of forces: “Have not
the small particles of Bodies certain Powers, Virtues or Forces, by which they
act at a distance, not only upon the Rays of Light for reflecting, refracting, and
inflecting them [as particles], but also upon one another for producing a great
Part of the Phaenomena of Nature?”
He extracts, from his intimate knowledge of chemistry, evidence for attraction
and repulsion forces among particles of all kinds of chemical substances, metals,
salts, acids, solvents, oils, and vapors. He argues that the particles are kinetic
and indestructible: “All these things being considered, it seems probable to me,
that God in the Beginning form’d Matter in solid, massy, hard, impenetrable,
moveable Particles, of such Sizes and Figures, and in such Proportion to Space,
as most conduced to the End for which he form’d them; even so very hard, as
never to wear or break in pieces; no ordinary Power being able to divide what
God himself made one in the First Creation.”
London :
There were two great divides in Newton’s adult life: in the middle 1660s from
the rural surroundings of Lincolnshire to the academic world of Cambridge, and
thirty years later, when he was fifty-four, from the seclusion of Cambridge to the
social and political existence of a well-placed civil servant in London. The move
to London was probably inspired by a feeling that his rapidly growing fame
deserved a more material reward than anything offered by the Lucasian Profes
sorship. We can also surmise that he was guided by an awareness that his for
midable talent for creative work in science was fading.
In March 1696, Newton left Cambridge, took up residence in London, and
started a new career as warden of the Mint. The post was offered by Charles
Montague, a former student and intimate friend who had recently become chan
cellor of the exchequer. Montague described the warden’s office to Newton as a sinecure, noting that “it has not too much bus’nesse to require more attendance
than you may spare.” But that was not what Newton had in mind; it was not in
his character to perform any task, large or small, superficially.
Newton did what he always did whenconfrontedwithacomplicatedproblem:
he studied it. He bought books on economics, commerce, and finance, asked
searching questions, and wrote volumes of notes. It was fortunate for England
that he did. The master of the Mint, under whom the warden served, wasThomas
Neale, a speculator with more interest in improving his own fortune than in
coping with a monumental assignment then facing the Mint. The English cur
rency, and with it the Treasury, were in crisis. Two kinds of coins were in cir
culation, those produced by hammering a metal blank against a die, and those
made by special machinery that gave each coin a milled edge. The hammered
coins were easily counterfeited and clipped, and thus worth less than milled
coins of the same denomination. Naturally, the hammered coins were used and
the milled coins hoarded.
An escape from this threatening problem, general recoinage, had already been
mandated before Newton’s arrival at the Mint. He quickly took up the challenge
of the recoinage, although it was not one of his direct responsibilities as warden.
As Westfall comments, “[Newton] was a born administrator, and the Mint felt the
benefit of his presence.” By the end of 1696, less than a year after Newton went
to the Mint, the crisis was under control. Montague did not hesitate to say later
that, without Newton, the recoinage would have been impossible. In 1699 Neale
died, and Newton, who was by then master in fact if not in name, succeeded
him.
Newton’s personality held many puzzles. One of the deepest was his attitude
toward women. Apparently he never had a cordial relationship with his mother.
Aside from a woman with whom he had a youthful infatuation and to whom he
may have made a proposal of marriage, there was one other woman in Newton’s
life. She was Catherine Barton, the daughter of Newton’s half-sister Hannah
Smith. Her father, the Reverend Robert Barton, died in 1693, and sometime in
the late 1690s she went to live with Newton in London. She was charming and
beautiful and had many admirers, including Newton’s patron, Charles Montague.
She became Montague’s mistress, no doubt with Newton’s approval. The affair
endured; when he died, Montague left her a generous income. She was also a
friend of Jonathan Swift’s, and he mentioned her frequently in his collection of
letters, called Journal to Stella. Voltaire gossiped: “I thought...that Newton
made his fortune by his merit....Nosuch thing. Isaac Newton had a verycharm
ing niece...whomade a conquest of Minister Halifax [Montague]. Fluxions and
gravitation would have been of no use without a pretty niece.” After Montague’s
death, Barton married John Conduitt, a wealthy man who had made his fortune
in service to the British army. The marriage placed him conveniently (and he
was aptly named) for another career: he became an early Newton biographer.
Newton the administrator was a vital influence in the rescue of two institu
tions from the brink of disaster. In 1703, long after the recoinage crisis at the
Mint, he was elected to the presidency of the Royal Society. Like the Mint when
Newton arrived, the society was desperately in need of energetic leadership.
Since the early 1690s its presidents had been aristocrats who were little more
than figureheads. Newton quickly changed that image. He introduced the practice
of demonstrations at the meetings in the major fields of science (mathematics,
mechanics, astronomy and optics, biology, botany, and chemistry), found the
society a new home, and installed Halley as secretary, followed by other disci
ples. He restored the authority of the society, but he also used that authority to
get his way in two infamous disputes.
On April 16, 1705, Queen Anne knighted Newton at Trinity College, Cam
bridge. The ceremony appears to have been politically inspired by Montague
(Newton was then standing for Parliament), rather than being a recognition of
Newton’s scientific achievements. Political or not, the honor was the climactic
point for Newton during his London years.
More Disputes :
Newton was contentious, and his most persistent opponent was the equally con
tentious Robert Hooke. The Newton story is not complete without two more ac
counts of Newton in rancorous dispute. The first of these was a battle over as
tronomical data. John Flamsteed, the first Astronomer Royal, had a series of
observations of the Moon, which Newton believed he needed to verify and refine
his lunar perturbation theory. Flamsteed reluctantly supplied the requested ob
servations, but Newton found the data inaccurate, and Flamsteed took offense at
his critical remarks.
About ten years later, Newton was still not satisfied with his lunar theory and
still in need of Flamsteed’s Moon data. He was now president of the Royal So
ciety, and with his usual impatience, took advantage of his position and at
tempted to force Flamsteed to publish a catalogue of the astronomical data. Flam
steed resisted. Newton obtained the backing of Prince George, Queen Anne’s
husband, and Flamsteed grudgingly went ahead with the catalogue.
The scope of the project was not defined. Flamsteed wanted to include with
his own catalogue those of previous astronomers from Ptolemy to Hevelius, but
Newton wanted just the data needed for his own calculations. Flamsteed stalled
for several years, Prince George died, and as president of the Royal Society, New
ton assumed dictatorial control over the Astronomer Royal’s observations. Some
of the data were published as Historia coelestis (History of the Heavens) in 1712,
with Halley as the editor. Neither the publication nor its editor was acceptable
to Flamsteed.
Newton had won a battle but not the war. Flamsteed’s political fortunes rose,
and Newton’s declined, with the deaths of Queen Anne in 1714 and Montague
in 1715. Flamsteed acquired the remaining copies of Historia coelestis, separated
Halley’s contributions, and “made a sacrifice of them to Heavenly Truth” (mean
ing that he burned them). He then returned to the project he had planned before
Newton’s interference, and had nearly finished it when he died in 1719. The task
was completed by two former assistants and published as Historia coelestis bri
tannica in 1725. As for Newton, he never did get all the data he wanted, and
was finally defeated by the sheer difficulty of precise lunar calculations.
Another man who crossed Newton’s path and found himself in an epic dispute
was Gottfried Leibniz. This time the controversy concerned one of the most pre
cious of a scientist’s intellectual possessions: priority. Newton and Leibniz both
claimed to be the inventors of calculus.
There would have been no dispute if Newton had published a treatise com
posed in 1666 on his fluxion method. He did not publish that, or indeed any
other mathematical work, for another forty years. After 1676, however, Leibniz
was at least partially aware of Newton’s work in mathematics. In that year, New ton wrote two letters to Leibniz, outlining his recent research in algebra and on
f
luxions. Leibniz developed the basic concepts of his calculus in 1675, and pub
lished a sketchy account restricted to differentiation in 1684 without mentioning
Newton. For Newton, that publication and that omission were, as Westfall puts
it, Leibniz’s “original sin, which not even divine grace could justify.”
During the 1680s and 1690s, Leibniz developed his calculus further to include
integration, Newton composed (but did not publish) his De quadratura (quad
rature was an early term for integration), and John Wallis published a brief ac
count of fluxions in volume 2 of his Algebra. In 1699, a former Newton prote´ge´,
Nicholas Fatio de Duillier, published a technical treatise, Lineae brevissimi (Line
of Quickest Descent), in which he claimed that Newton was the first inventor,
and Leibniz the second inventor, of calculus. A year later, in a review of Fatio’s
Lineae, Leibniz countered that his 1684 book was evidence of priority.
The dispute was now ignited. It was fueled by another Newton disciple, John
Keill, who, in effect, accused Leibniz of plagiarism. Leibniz complained to the
secretary of the Royal Society, Hans Sloane, about Keill’s “impertinent accusa
tions.” This gave Newton the opportunity as president of the society to appoint
a committee to review the Keill and Leibniz claims. Not surprisingly, the com
mittee found in Newton’s favor, and the dispute escalated. Several attempts to
bring Newton and Leibniz together did not succeed. Leibniz died in 1716; that
cooled the debate, but did not extinguish it. Newtonians and Leibnizians con
fronted each other for at least five more years
Nearer the Gods :
Biographers and other commentators have never given us a consensus view of
Newton’s character. His contemporaries either saw him as all but divine or all
but monstrous, and opinions depended a lot on whether the author was friend
or foe. By the nineteenth century, hagiography had set in, and Newton as paragon
emerged. In our time, the monster model seems to be returning.
Onone assessment there should be no doubt: Newton was the greatest creative
genius physics has ever seen. None of the other candidates for the superlative
(Einstein, Maxwell, Boltzmann, Gibbs, and Feynman) has matched Newton’s
combined achievements as theoretician, experimentalist, and mathematician.
Newton was no exception to the rule that creative geniuses lead self-centered,
eccentric lives. He was secretive, introverted, lacking a sense of humor, and prud
ish. He could not tolerate criticism, and could be mean and devious in the treat
ment of his critics. Throughout his life he was neurotic, and at least once
succumbed to breakdown.
But he was no monster. He could be generous to colleagues, both junior and
senior, and to destitute relatives. In disputes, he usually gave no worse than he
received. He never married, but he was not a misogynist, as his fondness for
Catherine Barton attests. He was reclusive in Cambridge, where he had little
admiration for his fellow academics, but entertained well in the more stimulating
intellectual environment of London.
If you were to become a time traveler and meet Newton on a trip back to the
seventeenth century, you might find him something like the performer who first
exasperates everyone in sight and then goes on stage and sings like an angel. The
singing is extravagantly admired and the obnoxious behavior forgiven. Halley,
who was as familiar as anyone with Newton’s behavior, wrote in an ode to New ton prefacing the Principia that “nearer the gods no mortal can approach.” Albert
Einstein, no doubt equal in stature to Newton as a theoretician (and no paragon),
left this appreciation of Newton in a foreword to an edition of the Opticks:
Fortunate Newton, happy childhood of science! He who has time and tran
quility can by reading this book live again the wonderful events which the great
Newton experienced in his young days. Nature to him was an open book,whose
letters he could read without effort. The conceptions which he used to reduce
the material of experience to order seemed to flow spontaneously from expe
rience itself, from the beautiful experiments which he ranged in order like play
things and describes with an affectionate wealth of details. In one person he
combined the experimenter, the theorist, the mechanic and, not least, the artist
in exposition. He stands before us strong, certain, and alone: his joy in creation
and his minute precision are evident in every word and in every figure.
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