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Isaac Newton

By: History.com Editors

Updated: October 16, 2023 | Original: March 10, 2015

Sir Isaac NewtonENGLAND - JANUARY 01: Sir Isaac Newton (1642-1727) .Canvas. (Photo by Imagno/Getty Images) [Sir Isaac Newton (1642-1727) . Gemaelde.]

Isaac Newton is best know for his theory about the law of gravity, but his “Principia Mathematica” (1686) with its three laws of motion greatly influenced the Enlightenment in Europe. Born in 1643 in Woolsthorpe, England, Sir Isaac Newton began developing his theories on light, calculus and celestial mechanics while on break from Cambridge University.

Years of research culminated with the 1687 publication of “Principia,” a landmark work that established the universal laws of motion and gravity. Newton’s second major book, “Opticks,” detailed his experiments to determine the properties of light. Also a student of Biblical history and alchemy, the famed scientist served as president of the Royal Society of London and master of England’s Royal Mint until his death in 1727.

Isaac Newton: Early Life and Education

Isaac Newton was born on January 4, 1643, in Woolsthorpe, Lincolnshire, England. The son of a farmer who died three months before he was born, Newton spent most of his early years with his maternal grandmother after his mother remarried. His education was interrupted by a failed attempt to turn him into a farmer, and he attended the King’s School in Grantham before enrolling at the University of Cambridge’s Trinity College in 1661.

Newton studied a classical curriculum at Cambridge, but he became fascinated by the works of modern philosophers such as René Descartes, even devoting a set of notes to his outside readings he titled “Quaestiones Quaedam Philosophicae” (“Certain Philosophical Questions”). When the Great Plague shuttered Cambridge in 1665, Newton returned home and began formulating his theories on calculus, light and color, his farm the setting for the supposed falling apple that inspired his work on gravity.

Isaac Newton’s Telescope and Studies on Light

Newton returned to Cambridge in 1667 and was elected a minor fellow. He constructed the first reflecting telescope in 1668, and the following year he received his Master of Arts degree and took over as Cambridge’s Lucasian Professor of Mathematics. Asked to give a demonstration of his telescope to the Royal Society of London in 1671, he was elected to the Royal Society the following year and published his notes on optics for his peers.

Through his experiments with refraction, Newton determined that white light was a composite of all the colors on the spectrum, and he asserted that light was composed of particles instead of waves. His methods drew sharp rebuke from established Society member Robert Hooke, who was unsparing again with Newton’s follow-up paper in 1675.

Known for his temperamental defense of his work, Newton engaged in heated correspondence with Hooke before suffering a nervous breakdown and withdrawing from the public eye in 1678. In the following years, he returned to his earlier studies on the forces governing gravity and dabbled in alchemy.

Isaac Newton and the Law of Gravity

In 1684, English astronomer Edmund Halley paid a visit to the secluded Newton. Upon learning that Newton had mathematically worked out the elliptical paths of celestial bodies, Halley urged him to organize his notes.

The result was the 1687 publication of “Philosophiae Naturalis Principia Mathematica” (Mathematical Principles of Natural Philosophy), which established the three laws of motion and the law of universal gravity. Newton’s three laws of motion state that (1) Every object in a state of uniform motion will remain in that state of motion unless an external force acts on it; (2) Force equals mass times acceleration: F=MA and (3) For every action there is an equal and opposite reaction.

“Principia” propelled Newton to stardom in intellectual circles, eventually earning universal acclaim as one of the most important works of modern science. His work was a foundational part of the European Enlightenment .

With his newfound influence, Newton opposed the attempts of King James II to reinstitute Catholic teachings at English Universities. King James II was replaced by his protestant daughter Mary and her husband William of Orange as part of the Glorious Revolution of 1688, and Newton was elected to represent Cambridge in Parliament in 1689.

Newton moved to London permanently after being named warden of the Royal Mint in 1696, earning a promotion to master of the Mint three years later. Determined to prove his position wasn’t merely symbolic, Newton moved the pound sterling from the silver to the gold standard and sought to punish counterfeiters.

The death of Hooke in 1703 allowed Newton to take over as president of the Royal Society, and the following year he published his second major work, “Opticks.” Composed largely from his earlier notes on the subject, the book detailed Newton’s painstaking experiments with refraction and the color spectrum, closing with his ruminations on such matters as energy and electricity. In 1705, he was knighted by Queen Anne of England.

Isaac Newton: Founder of Calculus?

Around this time, the debate over Newton’s claims to originating the field of calculus exploded into a nasty dispute. Newton had developed his concept of “fluxions” (differentials) in the mid 1660s to account for celestial orbits, though there was no public record of his work.

In the meantime, German mathematician Gottfried Leibniz formulated his own mathematical theories and published them in 1684. As president of the Royal Society, Newton oversaw an investigation that ruled his work to be the founding basis of the field, but the debate continued even after Leibniz’s death in 1716. Researchers later concluded that both men likely arrived at their conclusions independent of one another.

Death of Isaac Newton

Newton was also an ardent student of history and religious doctrines, and his writings on those subjects were compiled into multiple books that were published posthumously. Having never married, Newton spent his later years living with his niece at Cranbury Park near Winchester, England. He died in his sleep on March 31, 1727, and was buried in Westminster Abbey .

A giant even among the brilliant minds that drove the Scientific Revolution, Newton is remembered as a transformative scholar, inventor and writer. He eradicated any doubts about the heliocentric model of the universe by establishing celestial mechanics, his precise methodology giving birth to what is known as the scientific method. Although his theories of space-time and gravity eventually gave way to those of Albert Einstein , his work remains the bedrock on which modern physics was built.

Isaac Newton Quotes

“If I have seen further it is by standing on the shoulders of Giants.”
“I can calculate the motion of heavenly bodies but not the madness of people.”
“What we know is a drop, what we don't know is an ocean.”
“Gravity explains the motions of the planets, but it cannot explain who sets the planets in motion.”
“No great discovery was ever made without a bold guess.”

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Isaac Newton

Isaac Newton was an English physicist and mathematician famous for his laws of physics. He was a key figure in the Scientific Revolution of the 17th century.

(1643-1727)

Who Was Isaac Newton?

Isaac Newton was a physicist and mathematician who developed the principles of modern physics, including the laws of motion and is credited as one of the great minds of the 17th-century Scientific Revolution .

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. In 1705, he was knighted by Queen Anne of England, making him Sir Isaac Newton.

Early Life and Family

Newton was born on January 4, 1643, in Woolsthorpe, Lincolnshire, England. Using the "old" Julian calendar, Newton's birth date is sometimes displayed as December 25, 1642.

Newton was the only son of a prosperous local farmer, also named Isaac, 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.

Isaac Newton's Education

Newton was 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 at age 12. Her plan was to make him a farmer and have him tend the farm. Newton failed miserably, as he found farming monotonous. Newton was soon 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.

Scientific Revolution

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 without honors or distinctions, his efforts won him the title of scholar and four years of financial support for future education.

In 1665, the bubonic plague that was ravaging Europe had come to Cambridge, forcing the university to close. After a two-year hiatus, Newton returned to Cambridge in 1667 and was elected a minor fellow at Trinity College, as he was still not considered a standout scholar.

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.

Isaac Newton’s Discoveries

Newton made discoveries in optics, motion and mathematics. Newton theorized that white light was a composite of all colors of the spectrum, and that light was composed of particles.

His momentous book on physics, Principia , contains information on nearly all of the essential concepts of physics except energy, ultimately helping him to explain the laws of motion and the theory of gravity. Along with mathematician Gottfried Wilhelm von Leibniz, Newton is credited for developing essential theories of calculus.

Isaac Newton Inventions

Newton's first major public scientific achievement was designing and constructing a reflecting telescope in 1668. As a professor at Cambridge, Newton was required to deliver an annual course of lectures and chose optics as his initial topic. He used his telescope to study optics and help 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 .

The Apple Myth

Between 1665 and 1667, Newton returned home from Trinity College to pursue his private study, as school was closed due to the Great Plague. Legend has it that, at this time, Newton experienced his famous inspiration of gravity with the falling apple. According to this common myth, Newton was sitting under an apple tree when a fruit fell and hit him on the head, inspiring him to suddenly come up with the theory of gravity.

While there is no evidence that the apple actually hit Newton on the head, he did see an apple fall from a tree, leading him to wonder why it fell straight down and not at an angle. Consequently, he began exploring the theories of motion and gravity.

It was during this 18-month hiatus as a student that Newton conceived many of his most important insights—including the method of infinitesimal calculus, the foundations for his theory of light and color, and the laws of planetary motion—that eventually led to the publication of his physics book Principia and his theory of gravity.

Isaac Newton’s Laws of Motion

In 1687, following 18 months of intense and effectively nonstop work, Newton published Philosophiae Naturalis Principia Mathematica (Mathematical Principles of Natural Philosophy) , most often known as Principia .

Principia is said to be the single most influential book on physics and possibly all of science. Its publication immediately raised Newton to international prominence.

Principia offers an exact quantitative description of bodies in motion, with three basic but important laws of motion:

A stationary body will stay stationary unless an external force is applied to it.

Force is equal to mass times acceleration, and a change in motion (i.e., change in speed) is proportional to the force applied.

For every action, there is an equal and opposite reaction.

Newton and the Theory of Gravity

Newton’s three basic laws of motion outlined in Principia helped him arrive at his theory of gravity. Newton’s law of universal gravitation states that two objects attract each other with a force of gravitational attraction that’s proportional to their masses and inversely proportional to the square of the distance between their centers.

These 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.

They also allowed him 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.

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Isaac Newton & Robert Hooke

Not everyone at the Royal Academy was enthusiastic about Newton’s discoveries in optics and 1672 publication of Opticks: Or, A treatise of the Reflections, Refractions, Inflections and Colours of Light . 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.

While Newton theorized that light was composed of particles, Hooke believed it 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 Royal Society altogether. He remained only when several other members assured him that the Fellows held him in high esteem.

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, which it was, in Newton’s Principia .

Upon the publication of the first edition of Principia in 1687, 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.

Newton, however, 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 acknowledgment 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 very 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.

Newton and Alchemy

Following the publication of Principia , Newton was ready for a new direction in life. He no longer found contentment in his position at Cambridge and 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.

Gold Standard

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.

Barton 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.

The Royal Society

In 1703, Newton was elected president of the Royal Society upon Robert Hooke's death. However, 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.

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.

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, 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."

QUICK FACTS

Name: Isaac Newton
Birth Year: 1643
Birth date: January 4, 1643
Birth City: Woolsthorpe, Lincolnshire, England
Birth Country: United Kingdom
Gender: Male
Best Known For: Isaac Newton was an English physicist and mathematician famous for his laws of physics. He was a key figure in the Scientific Revolution of the 17th century.
Science and Medicine
Technology and Engineering
Education and Academia
Astrological Sign: Capricorn
University of Cambridge, Trinity College
The King's School
Interesting Facts
Isaac Newton helped develop the principles of modern physics, including the laws of motion, and is credited as one of the great minds of the 17th-century Scientific Revolution.
In 1687, Newton 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's theory of gravity states that two objects attract each other with a force of gravitational attraction that’s proportional to their masses and inversely proportional to the square of the distance between their centers.
Death Year: 1727
Death date: March 31, 1727
Death City: London, England
Death Country: United Kingdom

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CITATION INFORMATION

Article Title: Isaac Newton Biography
Author: Biography.com Editors
Website Name: The Biography.com website
Url: https://www.biography.com/scientists/isaac-newton
Access Date:
Publisher: A&E; Television Networks
Last Updated: November 5, 2020
Original Published Date: April 3, 2014
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.
Plato is my friend, Aristotle is my friend, but my greatest friend is truth.
If I have seen further it is by standing on the shoulders of giants.
It is the perfection of God's works that they are all done with the greatest simplicity.
Every body continues in its state of rest, or of uniform motion in a right line, unless it is compelled to change that state by forces impressed upon it.
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 contrary parts.
I see I have made myself a slave to philosophy.
The changing of bodies into light, and light into bodies, is very conformable to the course of nature, which seems delighted with transmutations.
To explain all nature is too difficult a task for any one man or even for any one age. Tis much better to do a little with certainty and leave the rest for others that come after, then to explain all things by conjecture without making sure of any thing.
Truth is ever to be found in simplicity, and not in the multiplicity and confusion of things.
Atheism is so senseless and odious to mankind that it never had many professors.
Newton was not the first of the age of reason. He was the last of the magicians, the last of the Babylonians and Sumerians, the last great mind that looked out on the visible and intellectual world with the same eyes as those who began to build our intellectual inheritance rather less than 10,000 years ago.

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I INTRODUCTION

Newton, Sir Isaac (1642-1727), mathematician and physicist, one of the foremost scientific intellects of all time. Born at Woolsthorpe, near Grantham in Lincolnshire, where he attended school, he entered Cambridge University in 1661; he was elected a Fellow of Trinity College in 1667, and Lucasian Professor of Mathematics in 1669. He remained at the university, lecturing in most years, until 1696. Of these Cambridge years, in which Newton was at the height of his creative power, he singled out 1665-1666 (spent largely in Lincolnshire because of plague in Cambridge) as “the prime of my age for invention”. During two to three years of intense mental effort he prepared Philosophiae Naturalis Principia Mathematica ( Mathematical Principles of Natural Philosophy ) commonly known as the Principia, although this was not published until 1687.

As a firm opponent of the attempt by King James II to make the universities into Catholic institutions, Newton was elected Member of Parliament for the University of Cambridge to the Convention Parliament of 1689, and sat again in 1701-1702. Meanwhile, in 1696 he had moved to London as Warden of the Royal Mint. He became Master of the Mint in 1699, an office he retained to his death. He was elected a Fellow of the Royal Society of London in 1671, and in 1703 he became President, being annually re-elected for the rest of his life. His major work, Opticks, appeared the next year; he was knighted in Cambridge in 1705.

As Newtonian science became increasingly accepted on the Continent, and especially after a general peace was restored in 1714, following the War of the Spanish Succession, Newton became the most highly esteemed natural philosopher in Europe. His last decades were passed in revising his major works, polishing his studies of ancient history, and defending himself against critics, as well as carrying out his official duties. Newton was modest, diffident, and a man of simple tastes. He was angered by criticism or opposition, and harboured resentment; he was harsh towards enemies but generous to friends. In government, and at the Royal Society, he proved an able administrator. He never married and lived modestly, but was buried with great pomp in Westminster Abbey.

Newton has been regarded for almost 300 years as the founding examplar of modern physical science, his achievements in experimental investigation being as innovative as those in mathematical research. With equal, if not greater, energy and originality he also plunged into chemistry, the early history of Western civilization, and theology; among his special studies was an investigation of the form and dimensions, as described in the Bible, of Solomon’s Temple in Jerusalem.

In 1664, while still a student, Newton read recent work on optics and light by the English physicists Robert Boyle and Robert Hooke; he also studied both the mathematics and the physics of the French philosopher and scientist René Descartes. He investigated the refraction of light by a glass prism; developing over a few years a series of increasingly elaborate, refined, and exact experiments, Newton discovered measurable, mathematical patterns in the phenomenon of colour. He found white light to be a mixture of infinitely varied coloured rays (manifest in the rainbow and the spectrum), each ray definable by the angle through which it is refracted on entering or leaving a given transparent medium. He correlated this notion with his study of the interference colours of thin films (for example, of oil on water, or soap bubbles), using a simple technique of extreme acuity to measure the thickness of such films. He held that light consisted of streams of minute particles. From his experiments he could infer the magnitudes of the transparent “corpuscles” forming the surfaces of bodies, which, according to their dimensions, so interacted with white light as to reflect, selectively, the different observed colours of those surfaces.

The roots of these unconventional ideas were with Newton by about 1668; when first expressed (tersely and partially) in public in 1672 and 1675, they provoked hostile criticism, mainly because colours were thought to be modified forms of homogeneous white light. Doubts, and Newton’s rejoinders, were printed in the learned journals. Notably, the scepticism of Christiaan Huygens and the failure of the French physicist Edmé Mariotte to duplicate Newton’s refraction experiments in 1681 set scientists on the Continent against him for a generation. The publication of Opticks, largely written by 1692, was delayed by Newton until the critics were dead. The book was still imperfect: the colours of diffraction defeated Newton. Nevertheless, Opticks established itself, from about 1715, as a model of the interweaving of theory with quantitative experimentation.

III MATHEMATICS

In mathematics too, early brilliance appeared in Newton’s student notes. He may have learnt geometry at school, though he always spoke of himself as self-taught; certainly he advanced through studying the writings of his compatriots William Oughtred and John Wallis, and of Descartes and the Dutch school. Newton made contributions to all branches of mathematics then studied, but is especially famous for his solutions to the contemporary problems in analytical geometry of drawing tangents to curves (differentiation) and defining areas bounded by curves (integration). Not only did Newton discover that these problems were inverse to each other, but he discovered general methods of resolving problems of curvature, embraced in his “method of fluxions” and “inverse method of fluxions”, respectively equivalent to Leibniz’s later differential and integral calculus. Newton used the term “fluxion” (from Latin meaning “flow”) because he imagined a quantity “flowing” from one magnitude to another. Fluxions were expressed algebraically, as Leibniz’s differentials were, but Newton made extensive use also (especially in the Principia ) of analogous geometrical arguments. Late in life, Newton expressed regret for the algebraic style of recent mathematical progress, preferring the geometrical method of the Classical Greeks, which he regarded as clearer and more rigorous.

Newton’s work on pure mathematics was virtually hidden from all but his correspondents until 1704, when he published, with Opticks , a tract on the quadrature of curves (integration) and another on the classification of the cubic curves. His Cambridge lectures, delivered from about 1673 to 1683, were published in 1707.

The Calculus Priority Dispute

Newton had the essence of the methods of fluxions by 1666. The first to become known, privately, to other mathematicians, in 1668, was his method of integration by infinite series. In Paris in 1675 Gottfried Wilhelm Leibniz independently evolved the first ideas of his differential calculus, outlined to Newton in 1677. Newton had already described some of his mathematical discoveries to Leibniz, not including his method of fluxions. In 1684 Leibniz published his first paper on calculus; a small group of mathematicians took up his ideas.

In the 1690s Newton’s friends proclaimed the priority of Newton’s methods of fluxions. Supporters of Leibniz asserted that he had communicated the differential method to Newton, although Leibniz had claimed no such thing. Newtonians then asserted, rightly, that Leibniz had seen papers of Newton’s during a London visit in 1676; in reality, Leibniz had taken no notice of material on fluxions. A violent dispute sprang up, part public, part private, extended by Leibniz to attacks on Newton’s theory of gravitation and his ideas about God and creation; it was not ended even by Leibniz’s death in 1716. The dispute delayed the reception of Newtonian science on the Continent, and dissuaded British mathematicians from sharing the researches of Continental colleagues for a century.

IV MECHANICS AND GRAVITATION

According to the well-known story, it was on seeing an apple fall in his orchard at some time during 1665 or 1666 that Newton conceived that the same force governed the motion of the Moon and the apple. He calculated the force needed to hold the Moon in its orbit, as compared with the force pulling an object to the ground. He also calculated the centripetal force needed to hold a stone in a sling, and the relation between the length of a pendulum and the time of its swing. These early explorations were not soon exploited by Newton, though he studied astronomy and the problems of planetary motion.

Correspondence with Hooke (1679-1680) redirected Newton to the problem of the path of a body subjected to a centrally directed force that varies as the inverse square of the distance; he determined it to be an ellipse, so informing Edmond Halley in August 1684. Halley’s interest led Newton to demonstrate the relationship afresh, to compose a brief tract on mechanics, and finally to write the Principia.

Book I of the Principia states the foundations of the science of mechanics, developing upon them the mathematics of orbital motion round centres of force. Newton identified gravitation as the fundamental force controlling the motions of the celestial bodies. He never found its cause. To contemporaries who found the idea of attractions across empty space unintelligible, he conceded that they might prove to be caused by the impacts of unseen particles.

Book II inaugurates the theory of fluids: Newton solves problems of fluids in movement and of motion through fluids. From the density of air he calculated the speed of sound waves.

Book III shows the law of gravitation at work in the universe: Newton demonstrates it from the revolutions of the six known planets, including the Earth, and their satellites. However, he could never quite perfect the difficult theory of the Moon’s motion. Comets were shown to obey the same law; in later editions, Newton added conjectures on the possibility of their return. He calculated the relative masses of heavenly bodies from their gravitational forces, and the oblateness of Earth and Jupiter, already observed. He explained tidal ebb and flow and the precession of the equinoxes from the forces exerted by the Sun and Moon. All this was done by exact computation.

Newton’s work in mechanics was accepted at once in Britain, and universally after half a century. Since then it has been ranked among humanity’s greatest achievements in abstract thought. It was extended and perfected by others, notably Pierre Simon de Laplace, without changing its basis and it survived into the late 19th century before it began to show signs of failing. See Quantum Theory; Relativity.

V ALCHEMY AND CHEMISTRY

Newton left a mass of manuscripts on the subjects of alchemy and chemistry, then closely related topics. Most of these were extracts from books, bibliographies, dictionaries, and so on, but a few are original. He began intensive experimentation in 1669, continuing till he left Cambridge, seeking to unravel the meaning that he hoped was hidden in alchemical obscurity and mysticism. He sought understanding of the nature and structure of all matter, formed from the “solid, massy, hard, impenetrable, movable particles” that he believed God had created. Most importantly in the “Queries” appended to “Opticks” and in the essay “On the Nature of Acids” (1710), Newton published an incomplete theory of chemical force, concealing his exploration of the alchemists, which became known a century after his death.

VI HISTORICAL AND CHRONOLOGICAL STUDIES

Newton owned more books on humanistic learning than on mathematics and science; all his life he studied them deeply. His unpublished “classical scholia”explanatory notes intended for use in a future edition of the Principia reveal his knowledge of pre-Socratic philosophy; he read the Fathers of the Church even more deeply. Newton sought to reconcile Greek mythology and record with the Bible, considered the prime authority on the early history of mankind. In his work on chronology he undertook to make Jewish and pagan dates compatible, and to fix them absolutely from an astronomical argument about the earliest constellation figures devised by the Greeks. He put the fall of Troy at 904 BC, about 500 years later than other scholars; this was not well received.

VII RELIGIOUS CONVICTIONS AND PERSONALITY

Newton also wrote on Judaeo-Christian prophecy, whose decipherment was essential, he thought, to the understanding of God. His book on the subject, which was reprinted well into the Victorian Age, represented lifelong study. Its message was that Christianity went astray in the 4th century AD, when the first Council of Nicaea propounded erroneous doctrines of the nature of Christ. The full extent of Newton’s unorthodoxy was recognized only in the present century: but although a critic of accepted Trinitarian dogmas and the Council of Nicaea, he possessed a deep religious sense, venerated the Bible and accepted its account of creation. In late editions of his scientific works he expressed a strong sense of God’s providential role in nature.

VIII PUBLICATIONS

Newton published an edition of Geographia generalis by the German geographer Varenius in 1672. His own letters on optics appeared in print from 1672 to 1676. Then he published nothing until the Principia (published in Latin in 1687; revised in 1713 and 1726; and translated into English in 1729). This was followed by Opticks in 1704; a revised edition in Latin appeared in 1706. Posthumously published writings include The Chronology of Ancient Kingdoms Amended (1728), The System of the World (1728), the first draft of Book III of the Principia , and Observations upon the Prophecies of Daniel and the Apocalypse of St John (1733).

Contributed By: Alfred Rupert Hall

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Biography of Isaac Newton, Mathematician and Scientist

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Sir Isaac Newton (Jan. 4, 1643–March 31, 1727) was a superstar of physics, math, and astronomy even in his own time. He occupied the chair of Lucasian Professor of Mathematics at the University of Cambridge in England, the same role later filled, centuries later, by Stephen Hawking . Newton conceived of several laws of motion , influential mathematical principals which, to this day, scientists use to explain how the universe works.

Fast Facts: Sir Isaac Newton

Known For : Developed laws that explain how the universe works
Born : Jan. 4, 1643 in Lincolnshire, England
Parents : Isaac Newton, Hannah Ayscough
Died : March 20, 1727 in Middlesex, England
Education : Trinity College, Cambridge (B.A., 1665)
Published Works : De Analysi per Aequationes Numero Terminorum Infinitas (1669, published 1711), Philosophiae Naturalis Principia Mathematica (1687), Opticks (1704)
Awards and Honors : Fellowship of the Royal Society (1672), Knight Bachelor (1705)
Notable Quote : "If I have seen further than others, it is by standing upon the shoulders of giants."

Early Years and Influences

Newton was born in 1642 in a manor house in Lincolnshire, England. His father had died two months before his birth. When Newton was 3 his mother remarried and he remained with his grandmother. He was not interested in the family farm, so he was sent to Cambridge University to study.

Newton was born just a short time after the death of Galileo , one of the greatest scientists of all time. Galileo had proved that the planets revolve around the sun, not the earth as people thought at the time. Newton was very interested in the discoveries of Galileo and others. Newton thought the universe worked like a machine and that a few simple laws governed it. Like Galileo, he realized that mathematics was the way to explain and prove those laws.

Laws of Motion

Newton formulated laws of motion and gravitation. These laws are math formulas that explain how objects move when a force acts on them. Newton published his most famous book, "Principia," in 1687 while he was a mathematics professor at Trinity College in Cambridge. In "Principia," Newton explained three basic laws that govern the way objects move. He also described his theory of gravity, the force that causes things to fall down. Newton then used his laws to show that the planets revolve around the suns in orbits that are oval, not round.

The three laws are often called Newton’s Laws. The first law states that an object that is not being pushed or pulled by some force will stay still or will keep moving in a straight line at a steady speed. For example, if someone is riding a bike and jumps off before the bike is stopped, what happens? The bike continues on until it falls over. The tendency of an object to remain still or keep moving in a straight line at a steady speed is called inertia.

The second law explains how a force acts on an object. An object accelerates in the direction the force is moving it. If someone gets on a bike and pushes the pedals forward, the bike will begin to move. If someone gives the bike a push from behind, the bike will speed up. If the rider pushes back on the pedals, the bike will slow down. If the rider turns the handlebars, the bike will change direction.

The third law states that if an object is pushed or pulled, it will push or pull equally in the opposite direction. If someone lifts a heavy box, they use force to push it up. The box is heavy because it is producing an equal force downward on the lifter’s arms. The weight is transferred through the lifter’s legs to the floor. The floor also presses upward with an equal force. If the floor pushed back with less force, the person lifting the box would fall through the floor. If it pushed back with more force, the lifter would fly up in the air.

Importance of Gravity

When most people think of Newton, they think of him sitting under an apple tree observing an apple fall to the ground. When he saw the apple fall, Newton began to think about a specific kind of motion called gravity. Newton understood that gravity was a force of attraction between two objects. He also understood that an object with more matter or mass exerted the greater force or pulled smaller objects toward it. That meant that the large mass of the Earth pulled objects toward it. That is why the apple fell down instead of up and why people don’t float in the air.

He also thought that maybe gravity was not just limited to the Earth and the objects on the earth. What if gravity extended to the Moon and beyond? Newton calculated the force needed to keep the Moon moving around the earth. Then he compared it with the force that made the apple fall downward. After allowing for the fact that the Moon is much farther from the Earth and has a much greater mass, he discovered that the forces were the same and that the Moon is also held in orbit around Earth by the pull of earth’s gravity.

Disputes in Later Years and Death

Newton moved to London in 1696 to accept the position of warden of the Royal Mint. For many years afterward, he argued with Robert Hooke over who had actually discovered the connection between elliptical orbits and the inverse square law, a dispute that ended only with Hooke's death in 1703.

In 1705, Queen Anne bestowed a knighthood upon Newton, and thereafter he was known as Sir Isaac Newton. He continued his work, particularly in mathematics. This led to another dispute in 1709, this time with German mathematician Gottfried Leibniz. They both quarreled over which of them had invented calculus.

One reason for Newton's disputes with other scientists was his overwhelming fear of criticism, which led him to write, but then postpone publication of, his brilliant articles until after another scientist created similar work. Besides his earlier writings, "De Analysi" (which didn't see publication until 1711) and "Principia" (published in 1687), Newton's publications included "Optics" (published in 1704), "The Universal Arithmetic" (published in 1707), the "Lectiones Opticae" (published in 1729), the "Method of Fluxions" (published in 1736), and the "Geometrica Analytica" (printed in 1779).

On March 20, 1727, Newton died near London. He was buried in Westminster Abbey, the first scientist to receive this honor.

Newton’s calculations changed the way people understood the universe. Prior to Newton, no one had been able to explain why the planets stayed in their orbits. What held them in place? People had thought that the planets were held in place by an invisible shield. Newton proved that they were held in place by the sun’s gravity and that the force of gravity was affected by distance and mass. While he was not the first person to understand that the orbit of a planet was elongated like an oval, he was the first to explain how it worked.

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Famous Scientists

Isaac Newton

Isaac Newton is perhaps the greatest physicist who has ever lived. He and Albert Einstein are almost equally matched contenders for this title.

Each of these great scientists produced dramatic and startling transformations in the physical laws we believe our universe obeys, changing the way we understand and relate to the world around us.

Early Life and Education

Isaac Newton was born on January 4, 1643 in the tiny village of Woolsthorpe-by-Colsterworth, Lincolnshire, England.

His father, whose name was also Isaac Newton, was a farmer who died before Isaac Junior was born. Although comfortable financially, his father could not read or write.

His mother, Hannah Ayscough, married a churchman when Newton was three years old.

Newton disliked his mother’s new husband and did not join their household, living instead with his mother’s mother, Margery Ayscough.

His resentment of his mother and stepfather’s new life did not subside with time; as a teenager he threatened to burn their house down!

Beginning at age 12, Newton attended The King’s School, Grantham, where he was taught the classics, but no science or mathematics. When he was 17, his mother stopped his schooling so that he could become a farmer. Fortunately for the future of science Newton found he had neither aptitude nor liking for farming; his mother allowed him to return to school, where he finished as top student.

Servant and Undergraduate

In June 1661, age 18, Newton began studying for a law degree at Cambridge University’s Trinity College, earning money as a personal servant to wealthier students.

By the time he was a third-year student he was spending much of his time studying mathematics and natural philosophy (today we call it physics). He was also fascinated by alchemy, which is now categorized as a pseudoscience.

His natural philosophy lecturers based their courses on Aristotle’s incorrect ideas from Ancient Greek times. This was despite the fact that 25 years earlier, in 1638, Galileo Galilei had established a new scientific basis for the physics of motion with his masterpiece Two New Sciences .

Newton began to disregard the material taught at his college, preferring to study the recent (and more scientifically correct) works of Galileo, Boyle, Descartes, and Kepler. He wrote:

Reading the works of these great scientists, Newton grew more ambitious about making his own discoveries. While still working part-time as a servant, he wrote a note to himself. In it he posed questions not yet been answered by science. These included questions about gravity, the nature of light, the nature of color and vision, and atoms.

After three years at Cambridge, he won a four-year scholarship. This allowed him to give up working as a servant and devote his time fully to academic studies.

A Mind on Fire

In 1665, at age 22, a year after beginning his four-year scholarship, Newton made his first major discovery: this was in mathematics, where he discovered the generalized binomial theorem. He was awarded his B.A. degree in the same year.

By now his mind was ablaze with new ideas. He began making significant progress in three distinct fields – he would make some of his most profound discoveries in these fields:

calculus, the mathematics of change, which is vital to our understanding of the world around us
optics and the behavior of light

He did much of his work on these topics back home at Woolsthorpe-by-Colsterworth after the Great Plague forced Cambridge colleges to close.

Fellow and Lucasian Professor of Mathematics

At age 24, in 1667, Newton returned to Cambridge, where events moved quickly.

First he was elected as a fellow of Trinity College.

A year later, in 1668, he was awarded an M.A. degree.

A year after that, the Lucasian Professor of Mathematics at Trinity College, Isaac Barrow, resigned and Newton was appointed as his replacement; he was just 26 years old. Barrow, who had recommended Newton to succeed him, said of him:

Isaac Newton’s Scientific Achievements and Discoveries

Achievements in brief.

Isaac Newton, who was largely self-taught in mathematics and physics:

generalized the binomial theorem
showed that sunlight is made up of all of the colors of the rainbow. He used one glass prism to split a beam of sunlight into its separate colors, then another prism to recombine the rainbow colors to make a beam of white light again.
built the world’s first working reflecting telescope.
discovered/invented calculus, the mathematics of change, without which we could not understand the behavior of objects as tiny as electrons or as large as galaxies.
wrote the Principia , one of the most important scientific books ever written; in it he used mathematics to explain gravity and motion. ( Principia is pronounced with a hard c.)
discovered the law of universal gravitation, proving that the force holding the moon in orbit around the earth is the same force that causes an apple to fall from a tree.
formulated his three laws of motion – Newton’s Laws – which lie at the heart of the science of movement.
showed that Kepler’s laws of planetary motion are special cases of Newton’s universal gravitation.
proved that all objects moving through space under the influence of gravity must follow a path shaped in the form of one of the conic sections, such as a circle, an ellipse, or a parabola, hence explaining the paths all planets and comets follow.
showed that the tides are caused by gravitational interactions between the earth, the moon, and the sun.
predicted, correctly, that the earth is not perfectly spherical but is squashed into an oblate spheroid, larger around the equator than around the poles.
Used mathematics to model the movement of fluids – from which the concept of a Newtonian fluid comes.
devised Newton’s Method for finding the roots of mathematical functions.

Some Details about Newton’s Greatest Discoveries

Newton revealed his laws of motion and gravitation in his book the Principia . Just as few people at first could understand Albert Einstein’s general theory of relativity, few people understood the Principia . When Newton walked past them one day, one student remarked to another:

“There goes a man who has written a book that neither he nor anybody else understands.”

Newton’s ideas were spread by the small number of people who understood the Principia , and who were able to develop and convey its message in more accessible ways: people including Colin Maclaurin, Leonhard Euler , Joseph Louis Lagrange, Pierre Simon de Laplace, Willem Jacob’s Gravesande, William Whiston, John Theophilus Desaguliers, and David Gregory.

Newton was the first person to fully develop calculus. Calculus is the mathematics of change. Modern physics and physical chemistry would be impossible without it. Other academic disciplines such as biology and economics also rely heavily on calculus for analysis.

In his development of calculus Newton was influenced by Pierre de Fermat , who had shown specific examples in which calculus-like methods could be used. Newton was able to build on Fermat’s work and generalize calculus. Newton wrote that he had been guided by:

From Newton’s fertile mind came the ideas that we now call differential calculus, integral calculus, and differential equations.

Soon after Newton generalized calculus, Gottfried Leibniz achieved the same result. Today, most mathematicians give equal credit to Newton and Leibniz for calculus’s discovery.

Universal Gravitation and the Apple

He told people that seeing the apple’s fall made him wonder why it fell in a straight line towards the center of our planet rather than moving upwards or sideways.

Ultimately, he realized and proved that the force behind the apple’s fall also causes the moon to orbit the earth; and comets, the earth and other planets to orbit the sun. The force is felt throughout the universe, so Newton called it Universal Gravitation . In a nutshell, it says that mass attracts mass.

Newton discovered the equation that allows us to calculate the force of gravity between two objects.

Most people don’t like equations much: E = mc 2 is as much as they can stand, but, for the record, here’s Newton’s equation:

Newton’s equation says that you can calculate the gravitational force attracting one object to another by multiplying the masses of the two objects by the gravitational constant and dividing by the square of the distance between the objects’ centers.

Dividing by distance squared means Newton’s Law is an inverse-square law .

Newton proved mathematically that any object moving in space affected by an inverse-square law will follow a path in the shape of one of the conic sections, the shapes which fascinated Archimedes and other Ancient Greek mathematicians.

For example, planets follow elliptical paths; while comets follow elliptical, or parabolic or hyperbolic paths.

And that’s it! Newton showed everyone how, if they wished to, they could calculate the force of gravity between things such as people, planets, stars, and apples.

Newton’s Laws of Motion

Third Law: The rocket flies because of the upward thrust it gets as a reaction to the high speed gas particles pushing downward from its engines.

First law: Objects remain stationary or move at a constant velocity unless acted upon by an external force. This law was actually first stated by Galileo , whose influence Newton mentions several times in the Principia .

Second law: The force F on an object is equal to its mass m multiplied by its acceleration: F = ma.

Third law: When one object exerts a force on a second object, the second object exerts a force equal in size and opposite in direction on the first object.

With Newton’s calculus, universal gravitation, and laws of motion, you have enough knowledge at your fingertips to plot a course for a spaceship to any planet in our solar system or even another solar system!

And Isaac Newton figured it all out about 300 years before we actually did send a spaceship to the planets.

A Word of Caution Newton’s laws become increasingly inaccurate when speeds reach substantial fractions of the speed of light, or when the force of gravity is very large. Einstein’s equations are then required to produce reliable results.

Optics and Light

Newton was not just clever with his mind. He was also skilled in experimental methods and working with equipment.

He built the world’s first reflecting telescope. This telescope focuses light from a curved mirror. Reflecting telescopes have several advantages over earlier telescopes including:

they are cheaper to make
they are easier to make in large sizes, gathering more light, allowing higher magnification
they do not suffer from a focusing issue associated with lenses called chromatic aberration.

Newton also used glass prisms to establish that white light is not a simple phenomenon. He proved that it is made up of all of the colors of the rainbow, which could recombine to form white light again.

Newton’s crucial 1672 experiment with two prisms. The result absolutely demolished competing theories, such as the proposal that glass added the colors to sunlight.

Alchemy, Feuds, Religion, and Planets Orbiting Distant Stars

Although he is one of the greatest scientists in history, Newton’s laboratory papers show he probably devoted more of his time to alchemy than to anything we would recognize as science.

The Alchemist by Joseph Wright depicts Hennig Brand’s discovery of phosphorus. Brand was actually trying to discover the Philosophers’ Stone. Newton seems to have put more of his hours into alchemy than mathematics and physics.

Not surprisingly, Newton never found the Philosophers’ Stone. Given his towering contributions to real science, all we can do is wonder what else he might have achieved if he had not been such a passionate alchemist.

Despite his brilliance, Newton was a very insecure man: most historians trace this back to his childhood family difficulties.

Newton published very little work until his later years, because in his early years as a scientist, Robert Hooke disagreed strongly with a scientific paper Newton published. Newton took criticism of his work in a very personal way and developed a lifelong loathing for Hooke.

His lack of published work also caused a huge issue when Gottfried Leibniz starting publishing his own version of calculus. Newton was already a master of this branch of mathematics, but had published very little of it. Again Newton’s insecurity got the better of him, and he angrily accused Leibniz of stealing his work. The pros and cons of each man’s case have long been debated by historians. Most mathematicians regard Newton and Leibniz as equally responsible for the development of calculus.

Newton was a very religious man with somewhat unorthodox Protestant Christian views. He spent a great deal of time and wrote a large body of private works concerned with theology and his interpretation of the Bible.

His scientific work had revealed a universe that obeyed logical mathematical laws. He had also discovered that starlight and sunlight are the same, and he speculated that stars could have their own systems of planets orbiting them. He believed such a system could only have been made by God.

In 1696, Newton was appointed as a Warden of the Royal Mint. In 1700, he became Master of the Mint, leaving Cambridge for London, and more or less ending his scientific discovery work. He took his new role very seriously, going out into London’s taverns in disguise gathering evidence against counterfeiters.

In 1703, he was elected President of the Royal Society.

In 1705, he was knighted, becoming Sir Isaac Newton.

Isaac Newton died on March 31, 1727, age 84. He had never married and had no children.

He was buried in Westminster Abbey, London.

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Biography Online

Biography Sir Isaac Newton

Early Life of Newton

Sir Isaac Newton was born on Christmas Day, in 1643, to a relatively poor farming family. His father died three months before he was born. His mother later remarried, but her second husband did not get on with Isaac; leading to friction between Isaac and his parents. The young Isaac attended school at King’s School, Grantham in Lincolnshire (where his signature is still inscribed on the walls.) Isaac was one of the top students, but before completing his studies his mother withdrew him from school, so Isaac could work as a farmer. It was only through the intervention of the headmaster that Isaac was able to return to finish his studies; he passed his final exams with very good results and was able to go to Trinity College, Cambridge.

Newton at Cambridge

Sir Isaac Newton, has been referred to as one of the greatest geniuses of history. His mathematical and scientific achievements give credence to such a view. His many accomplishments in the field of science include:

Developing a theory of calculus . Unfortunately, at the same time as Newton, calculus was being developed by Leibniz. When Leibniz published his results, there was a bitter feud between the two men, with Newton claiming plagiarism. This bitter feud lasted until Leibniz death in 1713, it also extended between British mathematicians and the continent.

Mathematical achievements of Newton

Generalized binomial theorem
Newton’s identities,
Newton’s method,
Classified cubic plane curves (polynomials of degree three in two variables),
Substantial contributions to the theory of finite differences,
Use of fractional indices
Used geometry to derive solutions to Diophantine equations.
Used power series with confidence and to revert power series.
Discovered a new formula for pi.

Scientific Achievements of Newton

Optics – Newton made great advancements in the study of optics. In particular, he developed the spectrum by splitting white light through a prism.
Telescope – Made significant improvements to the development of the telescope. However, when his ideas were criticised by Hooke, Newton withdrew from the public debate. He developed an antagonistic and hostile attitude to Hooke, throughout his life.
Mechanics and Gravitation . In his famous book Principia Mathematica . (1687) Newton explained the three laws of motion that laid the framework for modern physics. This involved explaining planetary movements.

Newton hit on the head with an Apple

The most popular anecdote about Sir Isaac Newton is the story of how the theory of gravitation came to him, after being hit on the head with a falling apple. In reality, Newton and his friends may have exaggerated this story. Nevertheless, it is quite likely that seeing apples fall from trees may have influenced his theories of gravity.

Newton’s Religious Beliefs

As well as being a scientist, Newton actually spent more time investigating religious issues. He read the Bible daily, believing it to be the word of God. Nevertheless, he was not satisfied with the Christian interpretations of the Bible. For example, he rejected the philosophy of the Holy Trinity; his beliefs were closer to the Christian beliefs in Arianism (basically there was a difference between Jesus Christ and God)

Newton – Bible Code

Newton was fascinated with the early Church and also the last chapter of the Bible Revelations. He spent many hours poring over the Bible, trying to find the secret Bible Code. He was rumoured to be a Rosicrucian. The religious beliefs that Newton held could have caused serious embarrassment at the time. Because of this, he kept his views hidden, almost to the point of obsession. This desire for secrecy seemed to be part of his nature. It was only on his death that his papers were opened up. The bishop who first opened Newton’s box, actually found them too shocking for public release, therefore, they were kept closed for many more years.

Newton and Alchemy

Newton was also interested in alchemy. He experimented on many objects, using a lot of Mercury. Very high levels of mercury in his bloodstream may have contributed to his early death and irregularities in later life.

Newton was made a member of the Royal Society in 1703. He was also given the job of Master of Mint in 1717. He took this job seriously and unofficially was responsible for moving England from the silver standard to the gold standard.

Newton was an extraordinary polymath; the universe simply fascinated him. He sought to discover the hidden and outer mysteries of life. With his sharp intellect and powers of concentration, he was able to contribute to tremendous developments in many areas of science. He was a unique individual. John Maynard Keynes , a twentieth-century genius, said of Newton:

“I do not think that any one who has pored over the contents of that box which he packed up when he finally left Cambridge in 1696 and which, though partly dispersed, have come down to us, can see him like that. Newton was not the first of the age of reason. He was the last of the magicians, the last of the Babylonians and Sumerians, the last great mind which looked out on the visible and intellectual world with the same eyes as those who began to build our intellectual inheritance rather less than 10,000 years ago. Isaac Newton, a posthumous child born with no father on Christmas Day, 1642, was the last wonderchild to whom the Magi could do sincere and appropriate homage.” [1]

Citation: Pettinger, Tejvan . “Biography of Sir Isaac Newton”, Oxford, www.biographyonline.net , 18th May. 2009. Last updated 28 Feb 2018.

Further reading: Interesting facts about Isaac Newton

Isaac Newton

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Isaac Newton, the Royal Society, and the Birth of the Modern World

Isaac Newton, the Royal Society, and the Birth of the Modern World at Amazon

Inventions that changed the world – Famous inventions that made a great difference to the progress of the world, including aluminium, the telephone and the printing press.

[1] Keynes on Newton the Man

Sir Isaac Newton biography: Inventions, laws and quotes

A short history of Sir Isaac Newton, the mathematician and physicist that helped invent and explain some of the most fundamental laws of science.

painting of Sir Isaac Newton shows him with shoulder length gray wavy hair.

Isaac Newton's early life

Laws of motion

Isaac Newton's apple

Inventions and discoveries

Additional resources

Bibliography.

Sir Isaac Newton contributed significantly to the field of science over his lifetime. He invented calculus and provided a clear understanding of optics. But his most significant work had to do with forces, and specifically with the development of a universal law of gravitation and his laws of motion .

Isaac Newton was born on Christmas Day to a poor farming family in Woolsthorpe, England, in 1642. At the time of Newton's birth England used the Julian calendar, however, when England adopted the Gregorian calendar in 1752, his birthday became 4th January 1643.

Isaac Newton arrived in the world only a few months after his father, Isaac Newton Sr, had died. "The boy expected to live managing the farm in the place of the father he had never known," wrote James Gleick in "Isaac Newton" ( Vintage, 2004 ).

However, when it became clear a farming life was not for him, Newton attended Trinity College in Cambridge, England. "He did not know what he wanted to be or do, but it was not tend sheep or follow the plough and the dung cart," wrote Gleick. While there, he took an interest in mathematics, optics, physics, and astronomy .

After his graduation, he began to teach at the college and was appointed as the second Lucasian Chair there. Today, the chair is considered the most renowned academic chair in the world, held by the likes of Charles Babbage and Stephen Hawking .

In 1689, Newton was elected as a member of parliament for the university. In 1703, he was elected as president of the Royal Society, a fellowship of scientists that still exists today. He was knighted by Queen Anne in 1705. He never married.

What are Isaac Newton's laws of motion?

Newton's most famous work came with the publication of his " Philosophiae Naturalis Principia Mathematica " ("Mathematical Principles of Natural Philosophy"), generally called Principia. In it, he determined the three laws of motion for the universe .

Newton's first law describes how objects move at the same velocity unless an outside force acts upon them. (A force is something that causes or changes motion.) Thus, an object sitting on a table remains on the table until a force — the push of a hand, or gravity — acts upon it. Similarly, an object travels at the same speed unless it interacts with another force, such as friction.

His second law of motion provided a calculation for how forces interact. The law states that a force is equal to the change in the momentum (mass multiplied by velocity) per change in time. Therefore, when more force is applied to an object, its acceleration also increases, but when the mass of the object increases and the force remains constant, its acceleration decreases.

Newton's third law states that for every action in nature, there is an equal and opposite reaction. If one body applies a force on a second, then the second body exerts a force of the same strength on the first, in the opposite direction.

From all of this, Newton calculated the universal law of gravitation. He found that as two bodies move farther away from one another, the gravitational attraction between them decreases by the inverse of the square of the distance. Thus, if the objects are twice as far apart, the gravitational force is only a fourth as strong; if they are three times as far apart, it is only a ninth of its previous power.

These laws helped scientists understand more about the motions of planets in the solar system , and of the moon around Earth.

Related: What makes Newton's laws work? Here's the simple trick.

A popular myth tells of an apple falling from a tree in Newton's garden, which brought Newton to an understanding of forces, particularly gravity. Whether the incident actually happened is unknown, but historians doubt the event — if it occurred — was the driving force in Newton's thought process.

The myth tells of Isaac Newton having returned to his family farm in Woolsthorpe, escaping Cambridge for a short time as it was dealing with a plague outbreak. As he sat in the farm's orchard, an apple fell from one of the trees (in some tellings it hit Newton on the head). Watching this happen, Newton began to consider the forces that meant the apple always fell directly towards the ground, beginning his examination of gravity.

One of the reasons that this story gained a foothold in popular understanding is that it is an anecdote Newton himself seems to have shared. "Toward the end of his life, Newton told the apple anecdote around four times, although it only became well known in the nineteenth century," wrote Patricia Fara, a historian of science at the University of Cambridge, in a chapter of " Newton's Apple and Other Myths about Science " (Harvard University Press, 2020).

However, it would be at least 20 years before Newton published his theories on gravity. It seems more likely that Newton used the story as a means of connecting the concept of gravity's impact on objects on Earth with its impact on objects in space for his contemporary audience.

The apple tree in question — known as the "Flower of Kent" — still blooms in the orchard of Woolsthorpe Manor, and is now a popular tourist attraction.

Isaac Newton's inventions and discoveries

Isaac Newton experimenting with a prism and light.

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While a student, Newton was forced to take a two-year hiatus when plague closed Trinity College. At home, he continued to work with optics, using a prism to separate white light, and became the first person to argue that white light was a mixture of many types of rays, rather than a single entity. He continued working with light and color over the next few years and published his findings in " Opticks " in 1704.

Disturbed by the problems with telescopes at the time, he invented the reflecting telescope, grinding the mirror and building the tube himself. Relying on a mirror rather than lenses, the telescope presented a sharper image than refracting telescopes at the time. Modern techniques have reduced the problems caused by lenses, but large telescopes such as the James Webb Space Telescope use mirrors.

As a student, Newton studied the most advanced mathematical texts of his time. While on hiatus, he continued to study mathematics, laying the ground for differential and integral calculus. He united many techniques that had previously been considered separately, such as finding areas, tangents, and the lengths of curves. He wrote De Methodis Serierum et Fluxionum in 1671 but was unable to find a publisher.

Newton also established a cohesive scientific method, to be used across disciplines. Previous explorations of science varied depending on the field. Newton established a set format for experimentation still used today.

However, not all of Newton's ideas were quite as revolutionary. In P rincipia, Newton describes how rarefied vapor from comet tails is pulled into Earth's gravitational grasp and enables the movements of the planet's fluids along with the "most subtle and useful part of our air, and so much required to sustain the life of all things with us."

Isaac Newton quotes

"Amicus Plato amicus Aristoteles magis amica verita."

(Plato is my friend, Aristotle is my friend, but my greatest friend is truth.)

—Written in the margin of a notebook while a student at Cambridge. In Richard S. Westfall, Never at Rest (1980), 89.

"Genius is patience."

—The Homiletic Review, Vol. 83-84 (1922), Vol. 84, 290.

"If I have seen further it is by standing on the shoulders of giants."

—Letter to Robert Hooke (5 Feb 1675-6).In H. W. Turnbull (ed.), The Correspondence of Isaac Newton, 1, 1661-1675 (1959), Vol. 1, 416.

"I see I have made my self a slave to Philosophy."

—Letter to Henry Oldenburg (18 Nov 1676). In H. W. Turnbull (ed.), The Correspondence of Isaac Newton, 1676-1687 (1960), Vol. 2, 182.

"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 in now and then finding a smoother pebble or a prettier shell than ordinary, whilst the great ocean of truth lay all undiscovered before me."

—First reported in Joseph Spence, Anecdotes, Observations and Characters, of Books and Men (1820), Vol. 1 of 1966 edn, sect. 1259, p. 462

"To any action there is always an opposite and equal reaction; in other words, the actions of two bodies upon each other are always equal and always opposite in direction."

— The Principia: Mathematical Principles of Natural Philosophy (1687)

"Truth is ever to be found in simplicity, and not in the multiplicity and confusion of things."

—'Fragments from a Treatise on Revelation". In Frank E. Manuel, The Religion of Isaac Newton (1974), 120.

How did Sir Isaac Newton die?

Newton died in 1727 during his sleep at the age of 84. Although the cause of death is unknown, a 1979 study published by Newton's own Royal Society suggests mercury poisoning may have contributed to the decline of his physical and mental health. During the exhumation of his body, large amounts of mercury were found in the scientist's system, likely due to his work with alchemy. Newton conducted several experiments to convert base metals, such as mercury and copper into precious metals, such as gold and silver.

"In 1693 Newton suffered from insomnia and poor digestion; and he also wrote irrational letters to friends. Although most scholars have attributed Newton's breakdown to psychological factors, it is possible that mercury poisoning may have been the principal cause," wrote L. W. Johnson and M. L. Wolbarsht " Mercury Poisoning: A probable cause of Isaac Newton's physical and mental ills: Notes and Records of the Royal Society of London Vol. 34. No. 1. " .

After his death, his body was moved to a more prominent place in Westminster Abbey. His white and grey marble monument stands in the nave of the Abbey's choir screen and boasts sculptures of Newton lounging surrounded by children using the many instruments, such as telescopes, associated with Newton's work. The inscription on the monument — originally written in Latin — reads:

" Here is buried Isaac Newton, Knight, who by a strength of mind almost divine, and mathematical principles peculiarly his own, explored the course and figures of the planets, the paths of comets, the tides of the sea, the dissimilarities in rays of light, and, what no other scholar has previously imagined, the properties of the colours thus produced. Diligent, sagacious and faithful, in his expositions of nature, antiquity and the holy Scriptures, he vindicated by his philosophy the majesty of God mighty and good, and expressed the simplicity of the Gospel in his manners. Mortals rejoice that there has existed such and so great an ornament of the human race! He was born on 25th December 1642, and died on 20th March 1726. " The date of his death on his monument is given in the Julian calendar.

If you want to learn more about the impact of this celebrated scientist, then you should read about how Isaac Newton Changed the World . If you're wondering whether Newton's second law of motion works in space then an Astronaut has tested the theory out.

"Isaac Newton" by James Gleick (Vintage, 2004 )

" Mercury Poisoning: A probable cause of Isaac Newton's physical and mental ills: Notes and Records of the Royal Society of London Vol. 34. No. 1. " by L. W. Johnson and M. L. Wolbarsht (July 1979)

" The Mathematical Principles of Natural Philosophy " by Isaac Newton (Flame Tree Collections, 2020)

" Newton's Apple and Other Myths about Science " edited by Ronald L. Numbers and Kostas Kampourakis (Harvard University Press, 2020)

" Life After Gravity: Isaac Newton's London Career " by Patricia Fara (Oxford University Press, 2021)

"Isaac Newton" Stanford Encyclopedia of Philosophy (2007)

"Isaac Newton" University of St Andrews (2000)

"Sir Isaac Newton" Westminster Abbey (2023)

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Isaac Newton

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Isaac Newton (1642-1727) was an English mathematician and physicist widely regarded as the single most important figure in the Scientific Revolution for his three laws of motion and universal law of gravity. Newton's laws became a fundamental foundation of physics, while his discovery that white light is made up of a rainbow of colours revolutionised the field of optics.

Isaac Newton was born on 25 December 1642. His family in Woolsthorpe, Lincolnshire, was of the yeomanry class, but it was clear that Isaac was destined for a career other than farming. Isaac's father died a few months before he was born, and his stepfather, a minister, died when he was 14. His mother was Hannah Ayscough, and her second husband insisted that Isaac be separated from his mother for a number of years. Some historians have read into this period of neglect the cause of Newton's notoriously prickly character and hypersensitivity to criticism later in life.

The young Isaac had a prodigious interest in all things mechanical, and he made several working models of his own, but he did not do particularly well at school. He was mischievous and once sent out into the night sky a series of candle-lit lanterns, which startled the local villagers into thinking a shower of comets was about to strike them down. An uncle of Isaac was adamant he was sent to study law at Trinity College, Cambridge, in June 1661. It was not law, though, but mathematics at which the young scholar excelled.

Isaac supplemented his orthodox education by taking private lessons with the mathematician and theologian Isaac Barrow (1630-1677). Barrow would later recommend Newton for his own soon-to-be-vacant chair at Trinity College. Newton graduated in April 1665, but any hope of a quick career launch was scuppered when there was an outbreak of the Black Death plague . Isaac was obliged to return to the family home in Woolthorpe for a year or more.

Newton's Approach to Knowledge

Isaac did not waste his year of forced seclusion as he launched into a series of scientific investigations, so much so that he described 1665 to 1666 as his "year of wonder" (Burns, 217). Newton discovered "the binomial theory, the differential and integral calculus, and the refraction of light, and he began to work out the theory of universal gravitation" ( ibid ). Heady stuff. Newton was determined to use all manner of methodologies and thinking, from alchemy to mechanical philosophy , in order to find out scientific truths that can be expressed mathematically. To this end, he relentlessly squirrelled away kernels of ancient and contemporary knowledge, experimentation, and even lore in a few select and very private leather-bound volumes, thus preserving his findings for later consumption when his scientific theories became clearer. As Newton himself once stated in a private letter, "If I have seen further it is by standing on the shoulders of giants" (Wootton, 341).

Newton was also a Protestant Christian (although an unorthodox one in private) and saw no conflict in his endeavours to explain why things happened the way they do in the physical world with the story of the Bible . Indeed, the imperfections of the physical world his theories proved all required, Newton said, a Creator to adjust them every now and then. Some Christians saw this as denying the perfection of the Creator, others saw it as support for having a Creator in the first place. For Newton, space was "an eminent effect of God ," and "he seems to have gone so far as to later identify space with the immensity of God, so that the biblical pronouncements that 'In Him we live, and move, and have our being' (Acts 17:28) was taken quite literally" (Henry, 89).

Like many thinkers of the time, Newton was convinced that great knowledge had been gained and then lost over the centuries and so careful research of past intellectual endeavours was essential in order to recapture this lost wisdom (known as prisca sapientia ). This belief in a lost or secret knowledge – a peculiar eccentricity for a scientist – may also explain why Newton was notoriously reticent to publish his own discoveries. He seemed to relish secrecy, just as was the tradition of the great alchemists of the Middle Ages. Fortunately for the progress of humanity, Newton did eventually make his ground-breaking research public.

Newton's Spectrum of Light

Newton did not find the esteemed Royal Society very receptive to his new ideas, particularly on optics, and so he got his foot in the door of that institution by designing a reflective telescope in 1668. This type of telescope used a curved mirror made of a tin and copper alloy, which improved the clarity of the image seen by reducing chromatic aberration, that is, when all colours fail to converge in a single point (a problem of glass lenses at the time). Newton's telescope had a magnification of 40 times and was ten times shorter than the standard refracting telescope of the same strength would have been. The Royal Society was hooked, and Newton was elected to that learned body in 1672; he then submitted his research on optics, which had, in fact, made his super-duper telescope possible.

Between 1666 and 1668, Newton had conducted optical experiments where he captured a narrow beam of light through an aperture, which was then projected onto a wall in a dark room. The light was made to shine through a prism. Others had done this sort of thing before, but, significantly, Newton put his prism near the hole and far from the wall on which was projected a block of rainbow colours: red, orange, yellow, green, blue, indigo, and violet. Even more crucial – in what he called his experimentum crucis – Newton then had various colour beams of the split white light go through a second prism, and these left that second prism the same colour as they entered, i.e. they could not be split further. Newton was thus able to develop a new theory of light, which was that white light is made up of a spectrum of different colours, each with a different angle of refraction, just like a rainbow one could see in the sky after a shower of rain. In the rainbow in the sky, drops of water function as a prism, that is, the white light is refracted. Newton also discovered that in the tiny airspace between a lens and a sheet of glass, coloured concentric rings can be seen, and these are now called Newton's rings.

Newton's idea of heterogeneous light, published in Philosophical Transactions in 1672, went directly against the standard theory of the time, which was the inverse of Newton's. Champions of the standard theory included Robert Hooke (1635-1703), who dismissed Newton's theory and later even accused him of plagiarism (without foundation). Newton, who was "of somewhat paranoid temperament" (Burns, 73) and "socially dysfunctional" (Jardine, 36), promptly withdrew from the Royal Society and would not even accept its presidency until Hooke had departed this earth. In 1704, Newton finally published his work on light in detail in his Optics . It took some time for Newton's theory to become widely accepted, but it is now a cornerstone of the science of optics.

Newton's Law of Gravity

The German astronomer Johannes Kepler created the most accurate yet system of planetary astronomy, with the heavenly bodies moving in elliptical orbits around the Sun and not the traditional model of perfect circles as proposed by thinkers from Claudius Ptolemy (c. 100 to c. 170) to Nicolaus Copernicus (1473-1543). The discovery that the planets increased their speed as they drew closer to the Sun was essential for Newton to build his own work upon. Newton's law of gravity would provide the cause for Kepler's keen observations of elliptical planetary motions. Encouraged, both with words and money, by his good friend Edmund Halley (1656-1742), Newton finally presented his theory of gravity in Mathematical Principles of Natural Philosophy ( Philosophiae Naturalis Principia Mathematica ), published in 1687.

The effects of gravity have been known since antiquity. Ancient thinkers formed theories as to why objects fell to the ground, the most common being that this was because Earth was the very centre of the universe and so some mysterious force attracted all objects to the central point. Similarly, thinkers like Galileo Galilei (1564-1642) had pondered what kind of force was responsible for the Sun seemingly pulling orbiting planets more speedily to its centre the closer they got to it. Magnetism was often suggested as the answer, but many thinkers remained unconvinced.

An apple may not have actually fallen from a branch and hit Newton on the head, but it does seem that his observation of fruit falling set him pondering what force was involved and how to measure it. Newton had also noticed many other 'attractions' and 'repulsions' between many other objects and substances, and so he began to formulate a theory that could measure such phenomena and finally bring together (or at least reconcile) two ancient but often opposing strands of human thought: mechanics and mathematics.

In his Principia , Newton put forward his theory of universal gravitation, but first, he presented a system of mathematical laws, which became known as 'Newton's laws of motion', here summarised by W. E. Burns:

That there is an attractive force between bodies that varies with the inverse square of the distance between them – and Newton's three laws of motion – 1. a body at rest or in motion in a straight path will tend to stay in that state, 2. a change of motion in a body varies with the force impressed, and 3. each action has an equal and opposite reaction. (218)

Newton then presented his theory of gravity:

That between any two bodies in the universe there exists a force directly proportional to the product of the masses of the two bodies and inversely proportional to the square of their distance. (Burns, 245)

Newton's theory of gravity was universal because it applied to everything from spinning planets to the movement of comets to the tides of the sea to that apocryphal apple dropping from a tree. The law of gravity (actually called a 'law' by Newton only in his later Optics ) applied equally to terrestrial affairs and to the heavens. Newton could now make accurate predictions of the effects of gravity. This was a new science. Of course, not everyone immediately adopted Newton's theories. The mechanical philosophers and the Cartesian followers of René Descartes (1596-1650), for example, could not accept that one physical body can affect another body without something, a third element, touching the two. Put simply, gravity was rather mysterious, since nobody, not even Newton, knew where it came from, why it exists, and who or what ensures its persistence. Contemplation on this fact and the inference that these forces act without any consideration of humanity led in some ways to a disenchantment regarding a new and pitiless world, at least for those who did not believe that a god of some kind was behind it all.

Recognition: The Greatest Scientist

Newton's work on gravity was ultimately well received, particularly in England , and he was made a fellow of Trinity College in 1687. Two years later, Newton became the Lucasian Professor of Mathematics there. A circle of devoted international followers sprang up around Newton, including the Swiss mathematician Nicolas Fatio de Duillier (1664-1753), who became very close to him. From 1688, Newton became ambitious to forge a political career. The scientist had hoped to move to London but suffered a nervous breakdown in 1693, perhaps because of the end of his relationship with Fatio de Duillier but certainly made worse by his chronic insomnia and possibly even a consequence of mercury poisoning, a key ingredient of Newton's experiments in alchemy. Recovered by 1696, Newton was made the warden of the royal mint in the Tower of London , which carried with it both prestige and a handsome salary. Newton, taking a hands-on approach which had not been required for what was, in effect, an honorary position, impressed his employers so much that he was made the mint master in 1699. He performed the role with remarkable dedication for the next 28 years, much to the chagrin of the countless counterfeiters he identified (who were then invariably hanged).

It was also in 1699 that Newton was appointed a member of the French Royal Academy of Sciences, the first foreigner to gain entry. In 1703, he was elected President of the Royal Society, and he used his position to skew the society's endeavours much more towards practical experimentation (as opposed to merely reading the academic papers of others) throughout his tenure, which ended in 1727. Less admirable was his ongoing feud with the German mathematician Gottfried Wilhelm Leibniz , which significantly held back mathematics in Britain . Newton accused Leibniz of plagiarising his work on the calculus (a mathematical tool for calculating curves and their areas). In reality, both men had developed the calculus independently, and although most historians consider Newton to have got there first, Leibniz's version was superior. Newton was knighted by Anne, Queen of Great Britain (r. 1702-1714) in 1705, probably more for his service in the royal mint than his tremendous contribution to science, but, nevertheless, it was a memorable moment for all scientists past and present since he was the first to be so honoured.

Death & Legacy

Newton was famous in his own lifetime for his discoveries, as we have seen with his various appointments to prestigious institutions at home and abroad. Rather oddly for a man so associated with science, Newton spent his final years studying biblical prophecies, an area he believed was just as valid as scientific experimentation. Sir Isaac Newton died of kidney failure on 20 March 1727; he was 84 years old. He had never married and left no children. Newton was given a state funeral and buried in Westminster Abbey. Alexander Pope provided the memorable epitaph:

Nature and Nature's Laws lay hid by Night: GOD said, Let Newton be! And all was Light. (Wootton, 361)

Newton, in one of those statements he frequently made where one wonders if he is being genuinely modest, remarked upon his career and discoveries in the following terms:

I don't know what I may seem to the world but, as to myself, I seem to have been only like a boy playing on the sea-shore, and diverting myself in now and then finding a smoother pebble or a prettier shell than ordinary, whilst the great ocean of truth lay all undiscovered before me. (Gleick, 4)

There would be many more breakthroughs in science after Newton, but nothing as revolutionary as his work until the development in the 20th century of relativity and quantum physics.

There developed a definite movement, known as Newtonianism, which pushed the idea that scientific knowledge should be presented as a series of mathematical laws which could predict tendencies of motion in relation to hypothetical accelerative forces. In addition, because Newton's research was so complex and inaccessible to the majority, a great number of writers sprang up who simplified Newton's work so that it could be understood by the reasonably well-educated. Newtonianism gradually spread across Europe to become the dominant approach in universities and amongst intellectuals. Newton's approach to knowledge, spread to new minds by such thinkers as Voltaire (1694-1778) in his Elements of Newton's Philosophy (1738), was an important part of the Enlightenment movement, where the improvement of the human condition became the ultimate goal of philosophy and science, despite Newton having split those two disciplines apart forever. Even that great modern genius Albert Einstein (1879-1955), with his new theory of relativity, could not overthrow Newtonianism but only extend it to new and bold horizons. As Einstein once said of Newton: "He stands before us strong, certain, and alone" (Gleick, 9).

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Bibliography

Burns, William E. The Scientific Revolution in Global Perspective. Oxford University Press, 2015.
Burns, William E. The Scientific Revolution. ABC-CLIO, 2001.
Bynum, William F. & Browne, Janet & Porter, Roy. Dictionary of the History of Science . Princeton University Press, 1982.
Gleick, James. Isaac Newton. Vintage Books, 2023.
Henry. The Scientific Revolution and the Origins of Modern Science . Red Globe Press, 2008.
Jardine, Lisa. Ingenious Pursuits. Anchor, 2000.
Moran, Bruce T. Distilling Knowledge. Harvard University Press, 2005.
Wootton, David. The Invention of Science. Penguin UK, 2023.

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Isaac Newton

Introduction.

In 1661 Newton enrolled at Cambridge University. There he became interested in new scientific ideas that were coming out of Europe. They included the idea that Earth and the other planets travel around the sun. This idea challenged the long-held belief that Earth was the center of the universe.

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Isaac Newton made the world's first reflecting telescope in 1668.

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Isaac newton.

Occupation: Scientist, mathematician, and astronomer
Born: January 4, 1643 in Woolsthorpe, England
Best known for: Defining the three laws of motion and universal gravitation

Gravity - Newton is probably most famous for discovering gravity. Outlined in the Principia, his theory about gravity helped to explain the movements of the planets and the Sun. This theory is known today as Newton's law of universal gravitation.
Laws of Motion - Newton's laws of motion were three fundamental laws of physics that laid the foundation for classical mechanics.
Calculus - Newton invented a whole new type of mathematics which he called "fluxions." Today we call this math calculus and it is an important type of math used in advanced engineering and science.
Reflecting Telescope - In 1668 Newton invented the reflecting telescope . This type of telescope uses mirrors to reflect light and form an image. Nearly all of the major telescopes used in astronomy today are reflecting telescopes.
He studied many classic philosophers and astronomers such as Aristotle, Copernicus, Johannes Kepler, Rene Descartes, and Galileo.
Legend has it that Newton got his inspiration for gravity when he saw an apple fall from a tree on his farm.
He wrote his thoughts down in the Principia at the urging of his friend (and famous astronomer) Edmond Halley. Halley even paid for the book's publication.
He once said of his own work "If I have seen further than others, it is by standing upon the shoulders of giants."
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Table Of Contents

Newton was elected to a fellowship in Trinity College in 1667, after the university reopened. Two years later, Isaac Barrow , Lucasian professor of mathematics , who had transmitted Newton’s De Analysi to John Collins in London , resigned the chair to devote himself to divinity and recommended Newton to succeed him. The professorship exempted Newton from the necessity of tutoring but imposed the duty of delivering an annual course of lectures. He chose the work he had done in optics as the initial topic; during the following three years (1670–72), his lectures developed the essay “Of Colours” into a form which was later revised to become Book One of his Opticks .

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Beginning with Kepler’s Paralipomena in 1604, the study of optics had been a central activity of the Scientific Revolution . Descartes’s statement of the sine law of refraction , relating the angles of incidence and emergence at interfaces of the media through which light passes, had added a new mathematical regularity to the science of light, supporting the conviction that the universe is constructed according to mathematical regularities. Descartes had also made light central to the mechanical philosophy of nature; the reality of light, he argued, consists of motion transmitted through a material medium. Newton fully accepted the mechanical nature of light, although he chose the atomistic alternative and held that light consists of material corpuscles in motion. The corpuscular conception of light was always a speculative theory on the periphery of his optics, however. The core of Newton’s contribution had to do with colours . An ancient theory extending back at least to Aristotle held that a certain class of colour phenomena, such as the rainbow , arises from the modification of light, which appears white in its pristine form. Descartes had generalized this theory for all colours and translated it into mechanical imagery. Through a series of experiments performed in 1665 and 1666, in which the spectrum of a narrow beam was projected onto the wall of a darkened chamber, Newton denied the concept of modification and replaced it with that of analysis. Basically, he denied that light is simple and homogeneous—stating instead that it is complex and heterogeneous and that the phenomena of colours arise from the analysis of the heterogeneous mixture into its simple components. The ultimate source of Newton’s conviction that light is corpuscular was his recognition that individual rays of light have immutable properties; in his view, such properties imply immutable particles of matter. He held that individual rays (that is, particles of given size) excite sensations of individual colours when they strike the retina of the eye . He also concluded that rays refract at distinct angles—hence, the prismatic spectrum, a beam of heterogeneous rays, i.e., alike incident on one face of a prism , separated or analyzed by the refraction into its component parts—and that phenomena such as the rainbow are produced by refractive analysis. Because he believed that chromatic aberration could never be eliminated from lenses, Newton turned to reflecting telescopes ; he constructed the first ever built. The heterogeneity of light has been the foundation of physical optics since his time.

There is no evidence that the theory of colours, fully described by Newton in his inaugural lectures at Cambridge, made any impression, just as there is no evidence that aspects of his mathematics and the content of the Principia , also pronounced from the podium, made any impression. Rather, the theory of colours, like his later work, was transmitted to the world through the Royal Society of London, which had been organized in 1660. When Newton was appointed Lucasian professor, his name was probably unknown in the Royal Society; in 1671, however, they heard of his reflecting telescope and asked to see it. Pleased by their enthusiastic reception of the telescope and by his election to the society, Newton volunteered a paper on light and colours early in 1672. On the whole, the paper was also well received, although a few questions and some dissent were heard.

Among the most important dissenters to Newton’s paper was Robert Hooke , one of the leaders of the Royal Society who considered himself the master in optics and hence he wrote a condescending critique of the unknown parvenu. One can understand how the critique would have annoyed a normal man. The flaming rage it provoked, with the desire publicly to humiliate Hooke, however, bespoke the abnormal. Newton was unable rationally to confront criticism . Less than a year after submitting the paper, he was so unsettled by the give and take of honest discussion that he began to cut his ties, and he withdrew into virtual isolation.

In 1675, during a visit to London, Newton thought he heard Hooke accept his theory of colours. He was emboldened to bring forth a second paper, an examination of the colour phenomena in thin films , which was identical to most of Book Two as it later appeared in the Opticks . The purpose of the paper was to explain the colours of solid bodies by showing how light can be analyzed into its components by reflection as well as refraction . His explanation of the colours of bodies has not survived, but the paper was significant in demonstrating for the first time the existence of periodic optical phenomena. He discovered the concentric coloured rings in the thin film of air between a lens and a flat sheet of glass; the distance between these concentric rings ( Newton’s rings ) depends on the increasing thickness of the film of air. In 1704 Newton combined a revision of his optical lectures with the paper of 1675 and a small amount of additional material in his Opticks .

A second piece which Newton had sent with the paper of 1675 provoked new controversy. Entitled “An Hypothesis Explaining the Properties of Light,” it was in fact a general system of nature. Hooke apparently claimed that Newton had stolen its content from him, and Newton boiled over again. The issue was quickly controlled, however, by an exchange of formal, excessively polite letters that fail to conceal the complete lack of warmth between the men.

Newton was also engaged in another exchange on his theory of colours with a circle of English Jesuits in Liège, perhaps the most revealing exchange of all. Although their objections were shallow, their contention that his experiments were mistaken lashed him into a fury. The correspondence dragged on until 1678, when a final shriek of rage from Newton, apparently accompanied by a complete nervous breakdown, was followed by silence. The death of his mother the following year completed his isolation. For six years he withdrew from intellectual commerce except when others initiated a correspondence, which he always broke off as quickly as possible.

During his time of isolation, Newton was greatly influenced by the Hermetic tradition with which he had been familiar since his undergraduate days. Newton, always somewhat interested in alchemy , now immersed himself in it, copying by hand treatise after treatise and collating them to interpret their arcane imagery. Under the influence of the Hermetic tradition, his conception of nature underwent a decisive change. Until that time, Newton had been a mechanical philosopher in the standard 17th-century style, explaining natural phenomena by the motions of particles of matter. Thus, he held that the physical reality of light is a stream of tiny corpuscles diverted from its course by the presence of denser or rarer media. He felt that the apparent attraction of tiny bits of paper to a piece of glass that has been rubbed with cloth results from an ethereal effluvium that streams out of the glass and carries the bits of paper back with it. This mechanical philosophy denied the possibility of action at a distance; as with static electricity , it explained apparent attractions away by means of invisible ethereal mechanisms. Newton’s “Hypothesis of Light” of 1675, with its universal ether , was a standard mechanical system of nature. Some phenomena, such as the capacity of chemicals to react only with certain others, puzzled him, however, and he spoke of a “secret principle” by which substances are “sociable” or “unsociable” with others. About 1679, Newton abandoned the ether and its invisible mechanisms and began to ascribe the puzzling phenomena—chemical affinities , the generation of heat in chemical reactions , surface tension in fluids, capillary action , the cohesion of bodies, and the like—to attractions and repulsions between particles of matter. More than 35 years later, in the second English edition of the Opticks , Newton accepted an ether again, although it was an ether that embodied the concept of action at a distance by positing a repulsion between its particles. The attractions and repulsions of Newton’s speculations were direct transpositions of the occult sympathies and antipathies of Hermetic philosophy—as mechanical philosophers never ceased to protest. Newton, however, regarded them as a modification of the mechanical philosophy that rendered it subject to exact mathematical treatment. As he conceived of them, attractions were quantitatively defined, and they offered a bridge to unite the two basic themes of 17th-century science—the mechanical tradition, which had dealt primarily with verbal mechanical imagery, and the Pythagorean tradition, which insisted on the mathematical nature of reality. Newton’s reconciliation through the concept of force was his ultimate contribution to science.

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Isaac Newton Timeline
Timeline of important events in the life of English physicist and mathematician Isaac Newton who was the culminating figure of the Scientific Revolution of the 17th century. In mechanics, his three laws of motion, the basic principles of modern physics, resulted in the formulation of the law of universal gravitation.
Isaac Newton
Isaac Newton (born December 25, 1642 [January 4, 1643, New Style], Woolsthorpe, Lincolnshire, England—died March 20 [March 31], 1727, London) was an English physicist and mathematician who was the culminating figure of the Scientific Revolution of the 17th century. In optics, his discovery of the composition of white light integrated the phenomena of colours into the science of light and ...
Isaac Newton Timeline
Timeline. 1642 - 1727. Life of the scientist Isaac Newton. 25 Dec 1642. Isaac Newton is born in Woolsthorpe, Lincolnshire, England. 1665 - 1666. Isaac Newton 's 'year of wonder' when he makes many new scientific discoveries. Apr 1665. Isaac Newton graduates from Trinity College, Cambridge.
Isaac Newton Timeline
Detailed Timeline. 1642 - April - Marriage of Hannah Ayscough (d. 1679) and Isaac Newton. (1606-1642), an uneducated and illiterate yeoman. October - Newton's father dies six months after his marriage and nearly three months before the birth of his son; Isaac the father has been described as a 'wild, extravagant, and weak man'.
Isaac Newton
Sir Isaac Newton FRS (25 December 1642 - 20 March 1726/27 [a]) was an English polymath active as a mathematician, physicist, astronomer, alchemist, theologian, and author who was described in his time as a natural philosopher. [7] He was a key figure in the Scientific Revolution and the Enlightenment that followed. His pioneering book Philosophiæ Naturalis Principia Mathematica ...
Isaac Newton ‑ Facts, Biography & Laws
Sir Isaac Newton (1643‑1727) was an English mathematician and physicist who developed influential theories on light, calculus and celestial mechanics. Years of research culminated with the 1687 ...
Isaac Newton
Name: Isaac Newton. Birth Year: 1643. Birth date: January 4, 1643. Birth City: Woolsthorpe, Lincolnshire, England. Birth Country: United Kingdom. Gender: Male. Best Known For: Isaac Newton was an ...
Life and works of Isaac Newton
Isaac Newton Isaac Newton, portrait by Godfrey Kneller, 1689. Sir Isaac Newton, (born Jan. 4, 1643, Woolsthorpe, Lincolnshire, Eng.—died March 31, 1727, London), English physicist and mathematician. The son of a yeoman, he was raised by his grandmother. He was educated at Cambridge University (1661-65), where he discovered the work of René ...
Isaac Newton's Life
I INTRODUCTION. Newton, Sir Isaac (1642-1727), mathematician and physicist, one of the foremost scientific intellects of all time. Born at Woolsthorpe, near Grantham in Lincolnshire, where he attended school, he entered Cambridge University in 1661; he was elected a Fellow of Trinity College in 1667, and Lucasian Professor of Mathematics in 1669.
Biography of Isaac Newton, Mathematician and Scientist
Sir Isaac Newton (Jan. 4, 1643-March 31, 1727) was a superstar of physics, math, and astronomy even in his own time. He occupied the chair of Lucasian Professor of Mathematics at the University of Cambridge in England, the same role later filled, centuries later, by Stephen Hawking. Newton conceived of several laws of motion, influential ...
Isaac Newton
Fellow and Lucasian Professor of Mathematics. At age 24, in 1667, Newton returned to Cambridge, where events moved quickly. First he was elected as a fellow of Trinity College. A year later, in 1668, he was awarded an M.A. degree. A year after that, the Lucasian Professor of Mathematics at Trinity College, Isaac Barrow, resigned and Newton was ...
Biography Sir Isaac Newton
Biography Sir Isaac Newton. Sir Issac Newton (1643- 1726) was an English mathematician, physicist and scientist. He is widely regarded as one of the most influential scientists of all time, developing new laws of mechanics, gravity and laws of motion. His work Principia Mathematica (1687) laid the framework for the Scientific Revolution of the ...
Sir Isaac Newton biography: Inventions, laws and quotes
Isaac Newton was born on Christmas Day to a poor farming family in Woolsthorpe, England, in 1642. At the time of Newton's birth England used the Julian calendar, however, when England adopted the ...
Isaac Newton
Isaac Newton (1642-1727) was an English mathematician and physicist widely regarded as the single most important figure in the Scientific Revolution for his three laws of motion and universal law of gravity. Newton's laws became a fundamental foundation of physics, while his discovery that white light is made up of a rainbow of colours revolutionised the field of optics.
Sir Isaac Newton Online
Most famous for discovering the laws of gravity and motion, plus inventing physics and calculus, Isaac Newton is generally regarded as the most original and influential theorist in the history of science. Sir Isaac Newton Biography. Mini and detailed biography plus timeline with key events in the life of Sir Isaac Newton. Read Biography
Isaac Newton
Isaac Newton was born on December 25, 1642 (January 4, 1643, according to the modern calendar), in Woolsthorpe, England. His father was a farmer. He died before Isaac was born. Isaac was raised by his grandmother. In 1661 Newton enrolled at Cambridge University. There he became interested in new scientific ideas that were coming out of Europe.
Isaac Newton: Facts & Related Content
Also Known As. Sir Isaac Newton. Born. January 4, 1643 • England. Died. March 31, 1727 (aged 84) • London • England. Notable Works. "Opticks" • "Principia" • "The Method of Fluxions and Infinite Series". Subjects Of Study.
Biography for Kids: Scientist
Born: January 4, 1643 in Woolsthorpe, England. Died: March 31, 1727 in London, England. Best known for: Defining the three laws of motion and universal gravitation. Isaac Newton by Godfrey Kneller. Biography: Isaac Newton is considered one of the most important scientists in history. Even Albert Einstein said that Isaac Newton was the smartest ...
Isaac Newton
Newton's reconciliation through the concept of force was his ultimate contribution to science. Isaac Newton - Scientist, Physics, Mathematics: Newton was elected to a fellowship in Trinity College in 1667, after the university reopened. Two years later, Isaac Barrow, Lucasian professor of mathematics, who had transmitted Newton's De Analysi ...

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