Philosopher, Astronomer, Physicist, Scientist, Mathematician(1643–1727)
English physicist and mathematician Sir Isaac Newton, most famous for
his law of gravitation, was instrumental in the scientific revolution of
the 17th century.
Synopsis
Born on January 4, 1643, in
Woolsthorpe, England, Isaac Newton was an established physicist and
mathematician, and is credited as one of the great minds of the 17th
century Scientific Revolution. With discoveries in optics, motion and
mathematics, Newton developed the principles of modern physics. In 1687,
he published his most acclaimed work, Philosophiae Naturalis Principia Mathematica (Mathematical Principles of Natural Philosophy), which has been called the single most influential book on physics. Newton died in London on March 31, 1727.
Early Life
On
January 4, 1643, Isaac Newton was born in the hamlet of Woolsthorpe,
Lincolnshire, England (using the "old" Julien calendar, Newton's birth
date is sometimes displayed as December 25, 1642). He was the only son
of a prosperous local farmer, also named Isaac Newton, who died three
months before he was born. A premature baby born tiny and weak, Newton
was not expected to survive. When he was 3 years old, his mother, Hannah
Ayscough Newton, remarried a well-to-do minister, Barnabas Smith, and
went to live with him, leaving young Newton with his maternal
grandmother. The experience left an indelible imprint on Newton, later
manifesting itself as an acute sense of insecurity. He anxiously
obsessed over his published work, defending its merits with irrational
behavior.
At age 12, Newton was reunited with his mother after
her second husband died. She brought along her three small children from
her second marriage. Newton had been enrolled at the King's School in
Grantham, a town in Lincolnshire, where he lodged with a local
apothecary and was introduced to the fascinating world of chemistry. His
mother pulled him out of school, for her plan was to make him a farmer
and have him tend the farm. Newton failed miserably, as he found farming
monotonous.
He soon was sent back to King's School to
finish his basic education. Perhaps sensing the young man's innate
intellectual abilities, his uncle, a graduate of the University of
Cambridge's Trinity College, persuaded Newton's mother to have him enter
the university. Newton enrolled in a program similar to a work-study in
1661, and subsequently waited on tables and took care of wealthier
students' rooms.
When Newton arrived at Cambridge, the Scientific
Revolution of the 17th century was already in full force. The
heliocentric view of the universe—theorized by astronomers Nicolaus
Copernicus and Johannes Kepler, and later refined by Galileo—was well
known in most European academic circles. Philosopher René Descartes had
begun to formulate a new concept of nature as an intricate, impersonal
and inert machine. Yet, like most universities in Europe, Cambridge was
steeped in Aristotelian philosophy and a view of nature resting on a
geocentric view of the universe, dealing with nature in qualitative
rather than quantitative terms.
During his first three years at
Cambridge, Newton was taught the standard curriculum but was fascinated
with the more advanced science. All his spare time was spent reading
from the modern philosophers. The result was a less-than-stellar
performance, but one that is understandable, given his dual course of
study. It was during this time that Newton kept a second set of notes,
entitled "Quaestiones Quaedam Philosophicae" ("Certain Philosophical
Questions"). The "Quaestiones" reveal that Newton had discovered the new
concept of nature that provided the framework for the Scientific
Revolution.
Though Newton graduated with no honors or
distinctions, his efforts won him the title of scholar and four years of
financial support for future education. Unfortunately, in 1665, the
Great Plague that was ravaging Europe had come to Cambridge, forcing the
university to close. Newton returned home to pursue his private study.
It was during this 18-month hiatus that he conceived the method of
infinitesimal calculus, set foundations for his theory of light and
color, and gained significant insight into the laws of planetary
motion—insights that eventually led to the publication of his Principia in 1687. Legend has it that, at this time, Newton experienced his famous inspiration of gravity with the falling apple.
When
the threat of plague subsided in 1667, Newton returned to Cambridge and
was elected a minor fellow at Trinity College, as he was still not
considered a standout scholar. However, in the ensuing years, his
fortune improved. Newton received his Master of Arts degree in 1669,
before he was 27. During this time, he came across Nicholas Mercator's
published book on methods for dealing with infinite series. Newton
quickly wrote a treatise, De Analysi, expounding his own wider-ranging
results. He shared this with friend and mentor Isaac Barrow, but didn't
include his name as author.
In June 1669, Barrow shared the
unaccredited manuscript with British mathematician John Collins. In
August 1669, Barrow identified its author to Collins as "Mr. Newton ...
very young ... but of an extraordinary genius and proficiency in these
things." Newton's work was brought to the attention of the mathematics
community for the first time. Shortly afterward, Barrow resigned his
Lucasian professorship at Cambridge, and Newton assumed the chair.
Professional Life
As
a professor, Newton was exempted from tutoring but required to deliver
an annual course of lectures. He chose to deliver his work on optics as
his initial topic. Part of Newton's study of optics was aided with the
use of a reflecting telescope that he designed and constructed in
1668—his first major public scientific achievement. This invention
helped prove his theory of light and color. The Royal Society asked for a
demonstration of his reflecting telescope in 1671, and the
organization's interest encouraged Newton to publish his notes on light,
optics and color in 1672; these notes were later published as part of
Newton's Opticks: Or, A treatise of the Reflections, Refractions, Inflections and Colours of Light.
However, not everyone at the Royal
Academy was enthusiastic about Newton's discoveries in optics. Among the
dissenters was Robert Hooke, one of the original members of the Royal
Academy and a scientist who was accomplished in a number of areas,
including mechanics and optics. In his paper, Newton theorized that
white light was a composite of all colors of the spectrum, and that
light was composed of particles. Hooke believed that light was composed
of waves. Hooke quickly condemned Newton's paper in condescending terms,
and attacked Newton's methodology and conclusions.
Hooke was not
the only one to question Newton's work in optics. Renowned Dutch
scientist Christiaan Huygens and a number of French Jesuits also raised
objections. But because of Hooke's association with the Royal Society
and his own work in optics, his criticism stung Newton the worst. Unable
to handle the critique, he went into a rage—a reaction to criticism
that was to continue throughout his life.
Newton denied Hooke's
charge that his theories had any shortcomings, and argued the importance
of his discoveries to all of science. In the ensuing months, the
exchange between the two men grew more acrimonious, and soon Newton
threatened to quit the society altogether. He remained only when several
other members assured him that the Fellows held him in high esteem.
However,
the rivalry between Newton and Hooke would continue for several years
thereafter. Then, in 1678, Newton suffered a complete nervous breakdown
and the correspondence abruptly ended. The death of his mother the
following year caused him to become even more isolated, and for six
years he withdrew from intellectual exchange except when others
initiated correspondence, which he always kept short.
During his
hiatus from public life, Newton returned to his study of gravitation and
its effects on the orbits of planets. Ironically, the impetus that put
Newton on the right direction in this study came from Robert Hooke. In a
1679 letter of general correspondence to Royal Society members for
contributions, Hooke wrote to Newton and brought up the question of
planetary motion, suggesting that a formula involving the inverse
squares might explain the attraction between planets and the shape of
their orbits.
Subsequent exchanges transpired before Newton
quickly broke off the correspondence once again. But Hooke's idea was
soon incorporated into Newton's work on planetary motion, and from his
notes it appears he had quickly drawn his own conclusions by 1680,
though he kept his discoveries to himself.
In early 1684, in a
conversation with fellow Royal Society members Christopher Wren and
Edmond Halley, Hooke made his case on the proof for planetary motion.
Both Wren and Halley thought he was on to something, but pointed out
that a mathematical demonstration was needed. In August 1684, Halley
traveled to Cambridge to visit with Newton, who was coming out of his
seclusion. Halley idly asked him what shape the orbit of a planet would
take if its attraction to the sun followed the inverse square of the
distance between them (Hooke's theory).
Newton knew the answer,
due to his concentrated work for the past six years, and replied, "An
ellipse." Newton claimed to have solved the problem some 18 years prior,
during his hiatus from Cambridge and the plague, but he was unable to
find his notes. Halley persuaded him to work out the problem
mathematically and offered to pay all costs so that the ideas might be
published.
Publishing 'Principia'
In 1687, after 18 months of intense and effectively nonstop work, Newton published Philosophiae Naturalis Principia Mathematica (Mathematical Principles of Natural Philosophy). Said to be the single most influential book on physics and possibly all of science, it is most often known as Principia and contains information on nearly all of the essential concepts of physics, except energy.
The work offers an exact
quantitative description of bodies in motion in three basic laws: 1) A
stationary body will stay stationary unless an external force is applied
to it; 2) Force is equal to mass times acceleration, and a change in
motion is proportional to the force applied; and 3) For every action,
there is an equal and opposite reaction. These three laws helped
explain not only elliptical planetary orbits but nearly every other
motion in the universe: how the planets are kept in orbit by the pull of
the sun’s gravity; how the moon revolves around Earth and the moons of
Jupiter revolve around it; and how comets revolve in elliptical orbits
around the sun.
The laws also allowed Newton to calculate the
mass of each planet, calculate the flattening of the Earth at the poles
and the bulge at the equator, and how the gravitational pull of the sun
and moon create the Earth’s tides. In Newton's account, gravity kept the
universe balanced, made it work, and brought heaven and earth together
in one great equation.
Upon the publication of the first edition of Principia,
Robert Hooke immediately accused Newton of plagiarism, claiming that he
had discovered the theory of inverse squares and that Newton had stolen
his work. The charge was unfounded, as most scientists knew, for Hooke
had only theorized on the idea and had never brought it to any level of
proof. However, Newton was furious and strongly defended his
discoveries.
He withdrew all references to Hooke in his notes and threatened to withdraw from publishing the subsequent edition of Principia
altogether. Halley, who had invested much of himself in Newton's work,
tried to make peace between the two men. While Newton begrudgingly
agreed to insert a joint acknowledgement of Hooke's work (shared with
Wren and Halley) in his discussion of the law of inverse squares, it did
nothing to placate Hooke.
As the years went on, Hooke's life began to unravel. His beloved niece and companion died the same year that Principia
was published, in 1687. As Newton's reputation and fame grew, Hooke's
declined, causing him to become even more bitter and loathsome toward
his rival. To the bitter end, Hooke took every opportunity he could to
offend Newton. Knowing that his rival would soon be elected president of
the Royal Society, Hooke refused to retire until the year of his death,
in 1703.
International Prominence
Principia
immediately raised Newton to international prominence, and he
thereafter became more involved in public affairs. Consciously or
unconsciously, he was ready for a new direction in life. He no longer
found contentment in his position at Cambridge and he was becoming more
involved in other issues. He helped lead the resistance to King James
II's attempts to reinstitute Catholic teaching at Cambridge, and in 1689
he was elected to represent Cambridge in Parliament.
While in
London, Newton acquainted himself with a broader group of intellectuals
and became acquainted with political philosopher John Locke. Though
many of the scientists on the continent continued to teach the
mechanical world according to Aristotle, a young generation of British
scientists became captivated with Newton's new view of the physical
world and recognized him as their leader. One of these admirers was
Nicolas Fatio de Duillier, a Swiss mathematician whom Newton befriended
while in London.
However, within a few years, Newton fell into
another nervous breakdown in 1693. The cause is open to speculation:
his disappointment over not being appointed to a higher position by
England's new monarchs, William III and Mary II, or the subsequent loss
of his friendship with Duillier; exhaustion from being overworked; or
perhaps chronic mercury poisoning after decades of alchemical research.
It's difficult to know the exact cause, but evidence suggests that
letters written by Newton to several of his London acquaintances and
friends, including Duillier, seemed deranged and paranoiac, and accused
them of betrayal and conspiracy.
Oddly enough, Newton recovered quickly, wrote letters of apology to
friends, and was back to work within a few months. He emerged with all
his intellectual facilities intact, but seemed to have lost interest in
scientific problems and now favored pursuing prophecy and scripture
and the study of alchemy. While some might see this as work beneath the
man who had revolutionized science, it might be more properly
attributed to Newton responding to the issues of the time in turbulent
17th century Britain. Many intellectuals were grappling with the
meaning of many different subjects, not least of which were religion,
politics and the very purpose of life. Modern science was still so new
that no one knew for sure how it measured up against older
philosophies.
In 1696, Newton was able to attain the governmental
position he had long sought: warden of the Mint; after acquiring this
new title, he permanently moved to London and lived with his niece,
Catherine Barton. She was the mistress of Lord Halifax, a high-ranking
government official who was instrumental in having Newton promoted, in
1699, to master of the Mint—a position that he would hold until his
death. Not wanting it to be considered a mere honorary position, Newton
approached the job in earnest, reforming the currency and severely
punishing counterfeiters. As master of the Mint, Newton moved the
British currency, the pound sterling, from the silver to the gold
standard.
In 1703, Newton was elected president of the Royal
Society upon Robert Hooke's death. In 1705, he was knighted by Queen
Anne of England. By this point in his life, Newton's career in science
and discovery had given way to a career of political power and
influence.
Newton never seemed to understand the notion of
science as a cooperative venture, and his ambition and fierce defense
of his own discoveries continued to lead him from one conflict to
another with other scientists. By most accounts, Newton's tenure at the
society was tyrannical and autocratic; he was able to control the lives
and careers of younger scientists with absolute power.
In 1705,
in a controversy that had been brewing for several years, German
mathematician Gottfried Leibniz publicly accused Newton of plagiarizing
his research, claiming he had discovered infinitesimal calculus
several years before the publication of Principia. In 1712,
the Royal Society appointed a committee to investigate the matter. Of
course, since Newton was president of the society, he was able to
appoint the committee's members and oversee its investigation. Not
surprisingly, the committee concluded Newton's priority over the
discovery.
That same year, in another of Newton's more flagrant
episodes of tyranny, he published without permission the notes of
astronomer John Flamsteed. It seems the astronomer had collected a
massive body of data from his years at the Royal Observatory at
Greenwich, England. Newton had requested a large volume of Flamsteed's
notes for his revisions to Principia. Annoyed when Flamsteed
wouldn't provide him with more information as quickly as he wanted it,
Newton used his influence as president of the Royal Society to be named
the chairman of the body of "visitors" responsible for the Royal
Observatory.
He then tried to force the immediate publication of
Flamsteed's catalogue of the stars, as well as all of Flamsteed's
notes, edited and unedited. To add insult to injury, Newton arranged
for Flamsteed's mortal enemy, Edmund Halley, to prepare the notes for
press. Flamsteed was finally able to get a court order forcing Newton
to cease his plans for publication and return the notes—one of the few
times that Newton was bested by one of his rivals.
Final Years
Toward the end of this
life, Newton lived at Cranbury Park, near Winchester, England, with his
niece, Catherine (Barton) Conduitt, and her husband, John Conduitt. By
this time, Newton had become one of the most famous men in Europe. His
scientific discoveries were unchallenged. He also had become wealthy,
investing his sizable income wisely and bestowing sizable gifts to
charity. Despite his fame, Newton's life was far from perfect: He never
married or made many friends, and in his later years, a combination of
pride, insecurity and side trips on peculiar scientific inquiries led
even some of his few friends to worry about his mental stability.
By
the time he reached 80 years of age, Newton was experiencing digestion
problems, and had to drastically change his diet and mobility. Then, in
March 1727, Newton experienced severe pain in his abdomen and blacked
out, never to regain consciousness. He died the next day, on March 31,
1727, at the age of 84.
Isaac Newton's fame grew even more after
his death, as many of his contemporaries proclaimed him the greatest
genius who ever lived. Maybe a slight exaggeration, but his discoveries
had a large impact on Western thought, leading to comparisons to the
likes of Plato, Aristotle and Galileo.
Although his discoveries
were among many made during the Scientific Revolution, Isaac Newton's
universal principles of gravity found no parallels in science at the
time. Of course, Newton was proven wrong on some of his key assumptions.
In the 20th century, Albert Einstein would overturn Newton's concept of
the universe, stating that space, distance and motion were not absolute
but relative, and that the universe was more fantastic than Newton had
ever conceived.
Newton might not have been surprised: In his
later life, when asked for an assessment of his achievements, he
replied, "I do not know what I may appear to the world; but to myself I
seem to have been only like a boy playing on the seashore, and diverting
myself now and then in finding a smoother pebble or prettier shell than
ordinary, while the great ocean of truth lay all undiscovered before
me."
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