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Gravity

March 20, 2023

For other uses, see Gravity (disambiguation).

"Gravitation" and "Law of Gravity" redirect here. For other uses, see Gravitation (disambiguation) and Law of Gravity (disambiguation).

In physics, gravity (from Latin gravitas 'weight'[1]) is a fundamental interaction which causes mutual attraction between all things with mass or energy[clarification needed]. Gravity is, by far, the weakest of the four fundamental interactions, approximately 1038 times weaker than the strong interaction, 1036 times weaker than the electromagnetic force and 1029 times weaker than the weak interaction. As a result, it has no significant influence at the level of subatomic particles.[2] However, gravity is the most significant interaction between objects at the macroscopic scale, and it determines the motion of planets, stars, galaxies, and even light.

Stars from three massive galaxies (UGC 6945) are being attracted by gravity.

On Earth, gravity gives weight to physical objects, and the Moon's gravity is responsible for sublunar tides in the oceans (the corresponding antipodal tide is caused by the inertia of the Earth and Moon orbiting one another). Gravity also has many important biological functions, helping to guide the growth of plants through the process of gravitropism and influencing the circulation of fluids in multicellular organisms. Investigation into the effects of weightlessness has shown that gravity may play a role in immune system function and cell differentiation within the human body.

The gravitational attraction between the original gaseous matter in the universe allowed it to coalesce and form stars which eventually condensed into galaxies, so gravity is responsible for many of the large-scale structures in the universe. Gravity has an infinite range, although its effects become weaker as objects get farther away.

Gravity is most accurately described by the general theory of relativity (proposed by Albert Einstein in 1915), which describes gravity not as a force, but as the curvature of spacetime, caused by the uneven distribution of mass, and causing masses to move along geodesic lines. The most extreme example of this curvature of spacetime is a black hole, from which nothing—not even light—can escape once past the black hole's event horizon.[3] However, for most applications, gravity is well approximated by Newton's law of universal gravitation, which describes gravity as a force causing any two bodies to be attracted toward each other, with magnitude proportional to the product of their masses and inversely proportional to the square of the distance between them:

where F is the force, m1 and m2 are the masses of the objects interacting, r is the distance between the centers of the masses and G is the gravitational constant.

Current models of particle physics imply that the earliest instance of gravity in the universe, possibly in the form of quantum gravity, supergravity or a gravitational singularity, along with ordinary space and time, developed during the Planck epoch (up to 10−43 seconds after the birth of the universe), possibly from a primeval state, such as a false vacuum, quantum vacuum or virtual particle, in a currently unknown manner.[4] Scientists are currently working to develop a theory of gravity consistent with quantum mechanics, a quantum gravity theory,[5] which would allow gravity to be united in a common mathematical framework (a theory of everything) with the other three fundamental interactions of physics.

Definitions

Gravitation is the mutual attraction between all masses in the universe, also known as gravitational attration. Gravity is the gravitational attraction at the surface of a planet or other celestial body.[6]

History

Main article: History of gravitational theory

Ancient world

The nature and mechanism of gravity was explored by a wide range of ancient scholars. In Greece, Aristotle believed that objects fell towards the Earth because the Earth was the center of the Universe and attracted all of the mass in the Universe towards it. He also thought that the speed of a falling object should increase with its weight, a conclusion which was later shown to be false.[7] While Aristotle's view was widely accepted throughout Ancient Greece, there were other thinkers such as Plutarch who correctly predicted that the attraction of gravity was not unique to the Earth.[8]

Although he didn't understand gravity as a force, the ancient Greek philosopher Archimedes discovered the center of gravity of a triangle.[9] He also postulated that if two equal weights did not have the same center of gravity, the center of gravity of the two weights together would be in the middle of the line that joins their centers of gravity.[10]Two centuries later, the Roman engineer and architect Vitruvius contended in his De architectura that gravity is not dependent on a substance's weight but rather on its "nature".[11] In the 6th century CE, the Byzantine Alexandrian scholar John Philoponus proposed the theory of impetus, which modifies Aristotle's theory that "continuation of motion depends on continued action of a force" by incorporating a causative force which diminishes over time.

In India, the mathematician-astronomer Aryabhata first identified gravity to explain why objects are not driven away from the Earth by the centrifugal force of the planet's rotation. Later, in the seventh century CE, Brahmagupta proposed the idea that gravity is an attractive force which draws objects to the Earth and used the term gurutvākarṣaṇ to describe it.[12][13][14]

In the ancient Middle East, gravity was a topic of fierce debate. The Persian intellectual Al-Biruni believed that the force of gravity was not unique to the Earth, and he correctly assumed that other heavenly bodies should exert a gravitational attraction as well.[15] In contrast, Al-Khazini held the same position as Aristotle that all matter in the Universe is attracted to the center of the Earth.[16]

 
The Leaning Tower of Pisa, where according to legend Galileo performed an experiment about the speed of falling objects

Scientific revolution

Main article: Scientific revolution

In the mid-16th century, various European scientists experimentally disproved the Aristotelian notion that heavier objects fall at a faster rate.[17] In particular, the Spanish Dominican priest Domingo de Soto wrote in 1551 that bodies in free fall uniformly accelerate.[17] De Soto may have been influenced by earlier experiments conducted by other Dominican priests in Italy, including those by Benedetto Varchi, Francesco Beato, Luca Ghini, and Giovan Bellaso which contradicted Aristotle's teachings on the fall of bodies.[17] The mid-16th century Italian physicist Giambattista Benedetti published papers claiming that, due to specific gravity, objects made of the same material but with different masses would fall at the same speed.[18] With the 1586 Delft tower experiment, the Flemish physicist Simon Stevin observed that two cannonballs of differing sizes and weights fell at the same rate when dropped from a tower.[19] Finally, in the late 16th century, Galileo Galilei's careful measurements of balls rolling down inclines allowed him to firmly establish that gravitational acceleration is the same for all objects.[20] Galileo postulated that air resistance is the reason that objects with a low density and high surface area fall more slowly in an atmosphere.

In 1604, Galileo correctly hypothesized that the distance of a falling object is proportional to the square of the time elapsed.[21] This was later confirmed by Italian scientists Jesuits Grimaldi and Riccioli between 1640 and 1650. They also calculated the magnitude of the Earth's gravity by measuring the oscillations of a pendulum.[22]

Newton's theory of gravitation

Main article: Newton's law of universal gravitation
 
English physicist and mathematician, Sir Isaac Newton (1642–1727)

In 1684, Newton sent a manuscript to Edmond Halley titled De motu corporum in gyrum ('On the motion of bodies in an orbit'), which provided a physical justification for Kepler's laws of planetary motion.[23] Halley was impressed by the manuscript and urged Newton to expand on it, and a few years later Newton published a groundbreaking book called Philosophiæ Naturalis Principia Mathematica (Mathematical Principles of Natural Philosophy). In this book, Newton described gravitation as a universal force, and claimed that "the forces which keep the planets in their orbs must [be] reciprocally as the squares of their distances from the centers about which they revolve." This statement was later condensed into the following inverse-square law:

 
where F is the force, m1 and m2 are the masses of the objects interacting, r is the distance between the centers of the masses and G is the gravitational constant 6.674×10−11 m3⋅kg−1⋅s−2.[24]

Newton's Principia was well-received by the scientific community, and his law of gravitation quickly spread across the European world.[25] More than a century later, in 1821, his theory of gravitation rose to even greater prominence when it was used to predict the existence of Neptune. In that year, the French astronomer Alexis Bouvard used this theory to create a table modeling the orbit of Uranus, which was shown to differ significantly from the planet's actual trajectory. In order to explain this discrepancy, many astronomers speculated that there might be a large object beyond the orbit of Uranus which was disrupting its orbit. In 1846, the astronomers John Couch Adams and Urbain Le Verrier independently used Newton's law to predict Neptune's location in the night sky, and the planet was discovered there within a day.[26]

General relativity

See also: Introduction to general relativity

Eventually, astronomers noticed an eccentricity in the orbit of the planet Mercury which could not be explained by Newton's theory: the perihelion of the orbit was increasing by about 42.98 arcseconds per century. The most obvious explanation for this discrepancy was an as-yet-undiscovered celestial body (such as a planet orbiting the Sun even closer than Mercury), but all efforts to find such a body turned out to be fruitless. Finally, in 1915, Albert Einstein developed a theory of general relativity which was able to accurately model Mercury's orbit.[27]

In general relativity, the effects of gravitation are ascribed to spacetime curvature instead of a force. Einstein began to toy with this idea in the form of the equivalence principle, a discovery which he later described as "the happiest thought of my life."[28] In this theory, free fall is considered to be equivalent to inertial motion, meaning that free-falling inertial objects are accelerated relative to non-inertial observers on the ground.[29][30] In contrast to Newtonian physics, Einstein believed that it was possible for this acceleration to occur without any force being applied to the object.

Einstein proposed that spacetime is curved by matter, and that free-falling objects are moving along locally straight paths in curved spacetime. These straight paths are called geodesics. As in Newton's first law of motion, Einstein believed that a force applied to an object would cause it to deviate from a geodesic. For instance, people standing on the surface of the Earth are prevented from following a geodesic path because the mechanical resistance of the Earth exerts an upward force on them. This explains why moving along the geodesics in spacetime is considered inertial.

Einstein's description of gravity was quickly accepted by the majority of physicists, as it was able to explain a wide variety of previously baffling experimental results.[31] In the coming years, a wide range of experiments provided additional support for the idea of general relativity.[32][33][34][35] Today, Einstein's theory of relativity is used for all gravitational calculations where absolute precision is desired, although Newton's inverse-square law continues to be a useful and fairly accurate approximation.[36]

Modern research

In modern physics, general relativity remains the framework for the understanding of gravity.[37] Physicists continue to work to find solutions to the Einstein field equations that form the basis of general relativity, while some scientists have speculated that general relativity may not be applicable at all in certain scenarios.[36]

Einstein field equations

The Einstein field equations are a system of 10 partial differential equations which describe how matter affects the curvature of spacetime. The system is often expressed in the form

 
where Gμν is the Einstein tensor, gμν is the metric tensor, Tμν is the stress–energy tensor, Λ is the cosmological constant,   is the Newtonian constant of gravitation and   is the speed of light.[38] The constant   is referred to as the Einstein gravitational constant.[39]
 
An illustration of the Schwarzschild metric, which describes spacetime around a spherical, uncharged, and nonrotating object with mass

A major area of research is the discovery of exact solutions to the Einstein field equations. Solving these equations amounts to calculating a precise value for the metric tensor (which defines the curvature and geometry of spacetime) under certain physical conditions. There is no formal definition for what constitutes such solutions, but most scientists agree that they should be expressable using elementary functions or linear differential equations.[40] Some of the most notable solutions of the equations include:

  • The Schwarzschild solution, which describes spacetime surrounding a spherically symmetric non-rotating uncharged massive object. For compact enough objects, this solution generated a black hole with a central singularity.[41] At points far away from the central mass, the accelerations predicted by the Schwarzschild solution are practically identical to those predicted by Newton's theory of gravity.[42]
  • The Reissner–Nordström solution, which analyzes a non-rotating spherically symmetric object with charge and was independently discovered by several different researchers between 1916 and 1921.[43] In some cases, this solution can predict the existence of black holes with double event horizons.[44]
  • The Kerr solution, which generalizes the Schwarzchild solution to rotating massive objects. Because of the difficulty of factoring in the effects of rotation into the Einstein field equations, this solution was not discovered until 1963.[45]
  • The Kerr–Newman solution for charged, rotating massive objects. This solution was derived in 1964, using the same technique of complex coordinate transformation that was used for the Kerr solution.[46]
  • The cosmological Friedmann–Lemaître–Robertson–Walker solution, discovered in 1922 by Alexander Friedmann and then confirmed in 1927 by Georges Lemaître. This solution was revolutionary for predicting the expansion of the Universe, which was confirmed seven years later after a series of measurements by Edwin Hubble.[47] It even showed that general relativity was incompatible with a static universe, and Einstein later conceded that he had been wrong to design his field equations to account for a Universe that was not expanding.[48]

Today, there remain many important situations in which the Einstein field equations have not been solved. Chief among these is the two-body problem, which concerns the geometry of spacetime around two mutually interacting massive objects (such as the Sun and the Earth, or the two stars in a binary star system). The situation gets even more complicated when considering the interactions of three or more massive bodies (the "n-body problem"), and some scientists suspect that the Einstein field equations will never be solved in this context.[49] However, it is still possible to construct an approximate solution to the field equations in the n-body problem by using the technique of post-Newtonian expansion.[50] In general, the extreme nonlinearity of the Einstein field equations makes it difficult to solve them in all but the most specific cases.[51]

Gravity and quantum mechanics

Main articles: Graviton and Quantum gravity

Despite its success in predicting the effects of gravity at large scales, general relativity is ultimately incompatible with quantum mechanics. This is because general relativity describes gravity as a smooth, continuous distortion of spacetime, while quantum mechanics holds that all forces arise from the exchange of discrete particles known as quanta. This contradiction is especially vexing to physicists because the other three fundamental forces (strong force, weak force and electromagnetism) were reconciled with a quantum framework decades ago.[52] As a result, modern researchers have begun to search for a theory that could unite both gravity and quantum mechanics under a more general framework.[53]

One path is to describe gravity in the framework of quantum field theory, which has been successful to accurately describe the other fundamental interactions. The electromagnetic force arises from an exchange of virtual photons, where the QFT description of gravity is that there is an exchange of virtual gravitons.[54][55] This description reproduces general relativity in the classical limit. However, this approach fails at short distances of the order of the Planck length,[56] where a more complete theory of quantum gravity (or a new approach to quantum mechanics) is required.

Tests of general relativity

Testing the predictions of general relativity has historically been difficult, because they are almost identical to the predictions of Newtonian gravity for small energies and masses.[57] Still, since its development, an ongoing series of experimental results have provided support for the theory:[57]

 
The 1919 total solar eclipse provided one of the first opportunities to test the predictions of general relativity.
  • In 1919, the British astrophysicist Arthur Eddington was able to confirm the predicted gravitational lensing of light during that year's solar eclipse.[58][59] Eddington measured starlight deflections twice those predicted by Newtonian corpuscular theory, in accordance with the predictions of general relativity. Although Eddington's analysis was later disputed, this experiment made Einstein famous almost overnight and caused general relativity to become widely accepted in the scientific community.[60]
  • In 1959, American physicists Robert Pound and Glen Rebka performed an experiment in which they used gamma rays to confirm the prediction of gravitational time dilation. By sending the rays down a 74-foot tower and measuring their frequency at the bottom, the scientists confirmed that light is redshifted as it moves towards a source of gravity. The observed redshift also supported the idea that time runs more slowly in the presence of a gravitational field.[61]
  • The time delay of light passing close to a massive object was first identified by Irwin I. Shapiro in 1964 in interplanetary spacecraft signals.[62]
  • In 1971, scientists discovered the first-ever black hole in the galaxy Cygnus. The black hole was detected because it was emitting bursts of x-rays as it consumed a smaller star, and it came to be known as Cygnus X-1.[63] This discovery confirmed yet another prediction of general relativity, because Einstein's equations implied that light could not escape from a sufficiently large and compact object.[64]
  • General relativity states that gravity acts on light and matter equally, meaning that a sufficiently massive object could warp light around it and create a gravitational lens. This phenomenon was first confirmed by observation in 1979 using the 2.1 meter telescope at Kitt Peak National Observatory in Arizona, which saw two mirror images of the same quasar whose light had been bent around the galaxy YGKOW G1.[65][66]
  • Frame dragging, the idea that a rotating massive object should twist spacetime around it, was confirmed by Gravity Probe B results in 2011.[67][68]
  • In 2015, the LIGO observatory detected faint gravitational waves, the existence of which had been predicted by general relativity. Scientists believe that the waves emanated from a black hole merger that occurred 1.5 billion light-years away.[69]

Specifics

Earth's gravity

 
An initially-stationary object that is allowed to fall freely under gravity drops a distance that is proportional to the square of the elapsed time. This image spans half a second and was captured at 20 flashes per second.
Main article: Gravity of Earth

Every planetary body (including the Earth) is surrounded by its own gravitational field, which can be conceptualized with Newtonian physics as exerting an attractive force on all objects. Assuming a spherically symmetrical planet, the strength of this field at any given point above the surface is proportional to the planetary body's mass and inversely proportional to the square of the distance from the center of the body.

 
If an object with comparable mass to that of the Earth were to fall towards it, then the corresponding acceleration of the Earth would be observable.

The strength of the gravitational field is numerically equal to the acceleration of objects under its influence.[70] The rate of acceleration of falling objects near the Earth's surface varies very slightly depending on latitude, surface features such as mountains and ridges, and perhaps unusually high or low sub-surface densities.[71] For purposes of weights and measures, a standard gravity value is defined by the International Bureau of Weights and Measures, under the International System of Units (SI).

The force of gravity on Earth is the resultant (vector sum) of two forces:[72] (a) The gravitational attraction in accordance with Newton's universal law of gravitation, and (b) the centrifugal force, which results from the choice of an earthbound, rotating frame of reference. The force of gravity is weakest at the equator because of the centrifugal force caused by the Earth's rotation and because points on the equator are furthest from the center of the Earth. The force of gravity varies with latitude and increases from about 9.780 m/s2 at the Equator to about 9.832 m/s2 at the poles.[citation needed] Canada's Hudson Bay has less gravity than any place on Earth.[73]

Origin

The earliest gravity (possibly in the form of quantum gravity, supergravity or a gravitational singularity), along with ordinary space and time, developed during the Planck epoch (up to 10−43 seconds after the birth of the Universe), possibly from a primeval state (such as a false vacuum, quantum vacuum or virtual particle), in a currently unknown manner.[4]

Gravitational radiation

 
The LIGO Hanford Observatory located in Washington, United States, where gravitational waves were first observed in September 2015
Main article: Gravitational wave

General relativity predicts that energy can be transported out of a system through gravitational radiation. The first indirect evidence for gravitational radiation was through measurements of the Hulse–Taylor binary in 1973. This system consists of a pulsar and neutron star in orbit around one another. Its orbital period has decreased since its initial discovery due to a loss of energy, which is consistent for the amount of energy loss due to gravitational radiation. This research was awarded the Nobel Prize in Physics in 1993.[citation needed]

The first direct evidence for gravitational radiation was measured on 14 September 2015 by the LIGO detectors. The gravitational waves emitted during the collision of two black holes 1.3 billion light years from Earth were measured.[74][75] This observation confirms the theoretical predictions of Einstein and others that such waves exist. It also opens the way for practical observation and understanding of the nature of gravity and events in the Universe including the Big Bang.[76] Neutron star and black hole formation also create detectable amounts of gravitational radiation.[77] This research was awarded the Nobel Prize in Physics in 2017.[78]

Speed of gravity

Main article: Speed of gravity

In December 2012, a research team in China announced that it had produced measurements of the phase lag of Earth tides during full and new moons which seem to prove that the speed of gravity is equal to the speed of light.[79] This means that if the Sun suddenly disappeared, the Earth would keep orbiting the vacant point normally for 8 minutes, which is the time light takes to travel that distance. The team's findings were released in Science Bulletin in February 2013.[80]

In October 2017, the LIGO and Virgo detectors received gravitational wave signals within 2 seconds of gamma ray satellites and optical telescopes seeing signals from the same direction. This confirmed that the speed of gravitational waves was the same as the speed of light.[81]

Anomalies and discrepancies

Not to be confused with Gravity anomaly.

There are some observations that are not adequately accounted for, which may point to the need for better theories of gravity or perhaps be explained in other ways.

 
Rotation curve of a typical spiral galaxy: predicted (A) and observed (B). The discrepancy between the curves is attributed to dark matter.
  • Extra-fast stars: Stars in galaxies follow a distribution of velocities where stars on the outskirts are moving faster than they should according to the observed distributions of normal matter. Galaxies within galaxy clusters show a similar pattern. Dark matter, which would interact through gravitation but not electromagnetically, would account for the discrepancy. Various modifications to Newtonian dynamics have also been proposed.
  • Flyby anomaly: Various spacecraft have experienced greater acceleration than expected during gravity assist maneuvers.
  • Accelerating expansion: The metric expansion of space seems to be speeding up. Dark energy has been proposed to explain this. A recent alternative explanation is that the geometry of space is not homogeneous (due to clusters of galaxies) and that when the data are reinterpreted to take this into account, the expansion is not speeding up after all,[82] however this conclusion is disputed.[83]
  • Anomalous increase of the astronomical unit: Recent measurements indicate that planetary orbits are widening faster than if this were solely through the Sun losing mass by radiating energy.
  • Extra energetic photons: Photons travelling through galaxy clusters should gain energy and then lose it again on the way out. The accelerating expansion of the Universe should stop the photons returning all the energy, but even taking this into account photons from the cosmic microwave background radiation gain twice as much energy as expected. This may indicate that gravity falls off faster than inverse-squared at certain distance scales.[84]
  • Extra massive hydrogen clouds: The spectral lines of the Lyman-alpha forest suggest that hydrogen clouds are more clumped together at certain scales than expected and, like dark flow, may indicate that gravity falls off slower than inverse-squared at certain distance scales.[84]

Alternative theories

Main article: Alternatives to general relativity

Historical alternative theories

Modern alternative theories

See also

Footnotes

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References

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Further reading

External links

March 20, 2023
gravity, other, uses, disambiguation, gravitation, redirect, here, other, uses, gravitation, disambiguation, disambiguation, physics, gravity, from, latin, gravitas, weight, fundamental, interaction, which, causes, mutual, attraction, between, things, with, ma. For other uses see Gravity disambiguation Gravitation and Law of Gravity redirect here For other uses see Gravitation disambiguation and Law of Gravity disambiguation In physics gravity from Latin gravitas weight 1 is a fundamental interaction which causes mutual attraction between all things with mass or energy clarification needed Gravity is by far the weakest of the four fundamental interactions approximately 1038 times weaker than the strong interaction 1036 times weaker than the electromagnetic force and 1029 times weaker than the weak interaction As a result it has no significant influence at the level of subatomic particles 2 However gravity is the most significant interaction between objects at the macroscopic scale and it determines the motion of planets stars galaxies and even light Stars from three massive galaxies UGC 6945 are being attracted by gravity On Earth gravity gives weight to physical objects and the Moon s gravity is responsible for sublunar tides in the oceans the corresponding antipodal tide is caused by the inertia of the Earth and Moon orbiting one another Gravity also has many important biological functions helping to guide the growth of plants through the process of gravitropism and influencing the circulation of fluids in multicellular organisms Investigation into the effects of weightlessness has shown that gravity may play a role in immune system function and cell differentiation within the human body The gravitational attraction between the original gaseous matter in the universe allowed it to coalesce and form stars which eventually condensed into galaxies so gravity is responsible for many of the large scale structures in the universe Gravity has an infinite range although its effects become weaker as objects get farther away Gravity is most accurately described by the general theory of relativity proposed by Albert Einstein in 1915 which describes gravity not as a force but as the curvature of spacetime caused by the uneven distribution of mass and causing masses to move along geodesic lines The most extreme example of this curvature of spacetime is a black hole from which nothing not even light can escape once past the black hole s event horizon 3 However for most applications gravity is well approximated by Newton s law of universal gravitation which describes gravity as a force causing any two bodies to be attracted toward each other with magnitude proportional to the product of their masses and inversely proportional to the square of the distance between them F G m 1 m 2 r 2 displaystyle F G frac m 1 m 2 r 2 where F is the force m1 and m2 are the masses of the objects interacting r is the distance between the centers of the masses and G is the gravitational constant Current models of particle physics imply that the earliest instance of gravity in the universe possibly in the form of quantum gravity supergravity or a gravitational singularity along with ordinary space and time developed during the Planck epoch up to 10 43 seconds after the birth of the universe possibly from a primeval state such as a false vacuum quantum vacuum or virtual particle in a currently unknown manner 4 Scientists are currently working to develop a theory of gravity consistent with quantum mechanics a quantum gravity theory 5 which would allow gravity to be united in a common mathematical framework a theory of everything with the other three fundamental interactions of physics Contents 1 Definitions 2 History 2 1 Ancient world 2 2 Scientific revolution 2 3 Newton s theory of gravitation 2 4 General relativity 3 Modern research 3 1 Einstein field equations 3 2 Gravity and quantum mechanics 3 3 Tests of general relativity 4 Specifics 4 1 Earth s gravity 4 2 Origin 4 3 Gravitational radiation 4 4 Speed of gravity 5 Anomalies and discrepancies 6 Alternative theories 6 1 Historical alternative theories 6 2 Modern alternative theories 7 See also 8 Footnotes 9 References 10 Further reading 11 External linksDefinitionsGravitation is the mutual attraction between all masses in the universe also known as gravitational attration Gravity is the gravitational attraction at the surface of a planet or other celestial body 6 HistoryMain article History of gravitational theory Ancient world The nature and mechanism of gravity was explored by a wide range of ancient scholars In Greece Aristotle believed that objects fell towards the Earth because the Earth was the center of the Universe and attracted all of the mass in the Universe towards it He also thought that the speed of a falling object should increase with its weight a conclusion which was later shown to be false 7 While Aristotle s view was widely accepted throughout Ancient Greece there were other thinkers such as Plutarch who correctly predicted that the attraction of gravity was not unique to the Earth 8 Although he didn t understand gravity as a force the ancient Greek philosopher Archimedes discovered the center of gravity of a triangle 9 He also postulated that if two equal weights did not have the same center of gravity the center of gravity of the two weights together would be in the middle of the line that joins their centers of gravity 10 Two centuries later the Roman engineer and architect Vitruvius contended in his De architectura that gravity is not dependent on a substance s weight but rather on its nature 11 In the 6th century CE the Byzantine Alexandrian scholar John Philoponus proposed the theory of impetus which modifies Aristotle s theory that continuation of motion depends on continued action of a force by incorporating a causative force which diminishes over time In India the mathematician astronomer Aryabhata first identified gravity to explain why objects are not driven away from the Earth by the centrifugal force of the planet s rotation Later in the seventh century CE Brahmagupta proposed the idea that gravity is an attractive force which draws objects to the Earth and used the term gurutvakarṣaṇ to describe it 12 13 14 In the ancient Middle East gravity was a topic of fierce debate The Persian intellectual Al Biruni believed that the force of gravity was not unique to the Earth and he correctly assumed that other heavenly bodies should exert a gravitational attraction as well 15 In contrast Al Khazini held the same position as Aristotle that all matter in the Universe is attracted to the center of the Earth 16 The Leaning Tower of Pisa where according to legend Galileo performed an experiment about the speed of falling objects Scientific revolution Main article Scientific revolution In the mid 16th century various European scientists experimentally disproved the Aristotelian notion that heavier objects fall at a faster rate 17 In particular the Spanish Dominican priest Domingo de Soto wrote in 1551 that bodies in free fall uniformly accelerate 17 De Soto may have been influenced by earlier experiments conducted by other Dominican priests in Italy including those by Benedetto Varchi Francesco Beato Luca Ghini and Giovan Bellaso which contradicted Aristotle s teachings on the fall of bodies 17 The mid 16th century Italian physicist Giambattista Benedetti published papers claiming that due to specific gravity objects made of the same material but with different masses would fall at the same speed 18 With the 1586 Delft tower experiment the Flemish physicist Simon Stevin observed that two cannonballs of differing sizes and weights fell at the same rate when dropped from a tower 19 Finally in the late 16th century Galileo Galilei s careful measurements of balls rolling down inclines allowed him to firmly establish that gravitational acceleration is the same for all objects 20 Galileo postulated that air resistance is the reason that objects with a low density and high surface area fall more slowly in an atmosphere In 1604 Galileo correctly hypothesized that the distance of a falling object is proportional to the square of the time elapsed 21 This was later confirmed by Italian scientists Jesuits Grimaldi and Riccioli between 1640 and 1650 They also calculated the magnitude of the Earth s gravity by measuring the oscillations of a pendulum 22 Newton s theory of gravitation Main article Newton s law of universal gravitation English physicist and mathematician Sir Isaac Newton 1642 1727 In 1684 Newton sent a manuscript to Edmond Halley titled De motu corporum in gyrum On the motion of bodies in an orbit which provided a physical justification for Kepler s laws of planetary motion 23 Halley was impressed by the manuscript and urged Newton to expand on it and a few years later Newton published a groundbreaking book called Philosophiae Naturalis Principia Mathematica Mathematical Principles of Natural Philosophy In this book Newton described gravitation as a universal force and claimed that the forces which keep the planets in their orbs must be reciprocally as the squares of their distances from the centers about which they revolve This statement was later condensed into the following inverse square law F G m 1 m 2 r 2 displaystyle F G frac m 1 m 2 r 2 where F is the force m1 and m2 are the masses of the objects interacting r is the distance between the centers of the masses and G is the gravitational constant 6 674 10 11 m3 kg 1 s 2 24 Newton s Principia was well received by the scientific community and his law of gravitation quickly spread across the European world 25 More than a century later in 1821 his theory of gravitation rose to even greater prominence when it was used to predict the existence of Neptune In that year the French astronomer Alexis Bouvard used this theory to create a table modeling the orbit of Uranus which was shown to differ significantly from the planet s actual trajectory In order to explain this discrepancy many astronomers speculated that there might be a large object beyond the orbit of Uranus which was disrupting its orbit In 1846 the astronomers John Couch Adams and Urbain Le Verrier independently used Newton s law to predict Neptune s location in the night sky and the planet was discovered there within a day 26 General relativity See also Introduction to general relativity Eventually astronomers noticed an eccentricity in the orbit of the planet Mercury which could not be explained by Newton s theory the perihelion of the orbit was increasing by about 42 98 arcseconds per century The most obvious explanation for this discrepancy was an as yet undiscovered celestial body such as a planet orbiting the Sun even closer than Mercury but all efforts to find such a body turned out to be fruitless Finally in 1915 Albert Einstein developed a theory of general relativity which was able to accurately model Mercury s orbit 27 In general relativity the effects of gravitation are ascribed to spacetime curvature instead of a force Einstein began to toy with this idea in the form of the equivalence principle a discovery which he later described as the happiest thought of my life 28 In this theory free fall is considered to be equivalent to inertial motion meaning that free falling inertial objects are accelerated relative to non inertial observers on the ground 29 30 In contrast to Newtonian physics Einstein believed that it was possible for this acceleration to occur without any force being applied to the object Einstein proposed that spacetime is curved by matter and that free falling objects are moving along locally straight paths in curved spacetime These straight paths are called geodesics As in Newton s first law of motion Einstein believed that a force applied to an object would cause it to deviate from a geodesic For instance people standing on the surface of the Earth are prevented from following a geodesic path because the mechanical resistance of the Earth exerts an upward force on them This explains why moving along the geodesics in spacetime is considered inertial Einstein s description of gravity was quickly accepted by the majority of physicists as it was able to explain a wide variety of previously baffling experimental results 31 In the coming years a wide range of experiments provided additional support for the idea of general relativity 32 33 34 35 Today Einstein s theory of relativity is used for all gravitational calculations where absolute precision is desired although Newton s inverse square law continues to be a useful and fairly accurate approximation 36 Modern researchIn modern physics general relativity remains the framework for the understanding of gravity 37 Physicists continue to work to find solutions to the Einstein field equations that form the basis of general relativity while some scientists have speculated that general relativity may not be applicable at all in certain scenarios 36 Einstein field equations The Einstein field equations are a system of 10 partial differential equations which describe how matter affects the curvature of spacetime The system is often expressed in the formG m n L g m n k T m n displaystyle G mu nu Lambda g mu nu kappa T mu nu where Gmn is the Einstein tensor gmn is the metric tensor Tmn is the stress energy tensor L is the cosmological constant G displaystyle G is the Newtonian constant of gravitation and c displaystyle c is the speed of light 38 The constant k 8 p G c 4 displaystyle kappa frac 8 pi G c 4 is referred to as the Einstein gravitational constant 39 An illustration of the Schwarzschild metric which describes spacetime around a spherical uncharged and nonrotating object with mass A major area of research is the discovery of exact solutions to the Einstein field equations Solving these equations amounts to calculating a precise value for the metric tensor which defines the curvature and geometry of spacetime under certain physical conditions There is no formal definition for what constitutes such solutions but most scientists agree that they should be expressable using elementary functions or linear differential equations 40 Some of the most notable solutions of the equations include The Schwarzschild solution which describes spacetime surrounding a spherically symmetric non rotating uncharged massive object For compact enough objects this solution generated a black hole with a central singularity 41 At points far away from the central mass the accelerations predicted by the Schwarzschild solution are practically identical to those predicted by Newton s theory of gravity 42 The Reissner Nordstrom solution which analyzes a non rotating spherically symmetric object with charge and was independently discovered by several different researchers between 1916 and 1921 43 In some cases this solution can predict the existence of black holes with double event horizons 44 The Kerr solution which generalizes the Schwarzchild solution to rotating massive objects Because of the difficulty of factoring in the effects of rotation into the Einstein field equations this solution was not discovered until 1963 45 The Kerr Newman solution for charged rotating massive objects This solution was derived in 1964 using the same technique of complex coordinate transformation that was used for the Kerr solution 46 The cosmological Friedmann Lemaitre Robertson Walker solution discovered in 1922 by Alexander Friedmann and then confirmed in 1927 by Georges Lemaitre This solution was revolutionary for predicting the expansion of the Universe which was confirmed seven years later after a series of measurements by Edwin Hubble 47 It even showed that general relativity was incompatible with a static universe and Einstein later conceded that he had been wrong to design his field equations to account for a Universe that was not expanding 48 Today there remain many important situations in which the Einstein field equations have not been solved Chief among these is the two body problem which concerns the geometry of spacetime around two mutually interacting massive objects such as the Sun and the Earth or the two stars in a binary star system The situation gets even more complicated when considering the interactions of three or more massive bodies the n body problem and some scientists suspect that the Einstein field equations will never be solved in this context 49 However it is still possible to construct an approximate solution to the field equations in the n body problem by using the technique of post Newtonian expansion 50 In general the extreme nonlinearity of the Einstein field equations makes it difficult to solve them in all but the most specific cases 51 Gravity and quantum mechanics Main articles Graviton and Quantum gravity Despite its success in predicting the effects of gravity at large scales general relativity is ultimately incompatible with quantum mechanics This is because general relativity describes gravity as a smooth continuous distortion of spacetime while quantum mechanics holds that all forces arise from the exchange of discrete particles known as quanta This contradiction is especially vexing to physicists because the other three fundamental forces strong force weak force and electromagnetism were reconciled with a quantum framework decades ago 52 As a result modern researchers have begun to search for a theory that could unite both gravity and quantum mechanics under a more general framework 53 One path is to describe gravity in the framework of quantum field theory which has been successful to accurately describe the other fundamental interactions The electromagnetic force arises from an exchange of virtual photons where the QFT description of gravity is that there is an exchange of virtual gravitons 54 55 This description reproduces general relativity in the classical limit However this approach fails at short distances of the order of the Planck length 56 where a more complete theory of quantum gravity or a new approach to quantum mechanics is required Tests of general relativity Testing the predictions of general relativity has historically been difficult because they are almost identical to the predictions of Newtonian gravity for small energies and masses 57 Still since its development an ongoing series of experimental results have provided support for the theory 57 The 1919 total solar eclipse provided one of the first opportunities to test the predictions of general relativity In 1919 the British astrophysicist Arthur Eddington was able to confirm the predicted gravitational lensing of light during that year s solar eclipse 58 59 Eddington measured starlight deflections twice those predicted by Newtonian corpuscular theory in accordance with the predictions of general relativity Although Eddington s analysis was later disputed this experiment made Einstein famous almost overnight and caused general relativity to become widely accepted in the scientific community 60 In 1959 American physicists Robert Pound and Glen Rebka performed an experiment in which they used gamma rays to confirm the prediction of gravitational time dilation By sending the rays down a 74 foot tower and measuring their frequency at the bottom the scientists confirmed that light is redshifted as it moves towards a source of gravity The observed redshift also supported the idea that time runs more slowly in the presence of a gravitational field 61 The time delay of light passing close to a massive object was first identified by Irwin I Shapiro in 1964 in interplanetary spacecraft signals 62 In 1971 scientists discovered the first ever black hole in the galaxy Cygnus The black hole was detected because it was emitting bursts of x rays as it consumed a smaller star and it came to be known as Cygnus X 1 63 This discovery confirmed yet another prediction of general relativity because Einstein s equations implied that light could not escape from a sufficiently large and compact object 64 General relativity states that gravity acts on light and matter equally meaning that a sufficiently massive object could warp light around it and create a gravitational lens This phenomenon was first confirmed by observation in 1979 using the 2 1 meter telescope at Kitt Peak National Observatory in Arizona which saw two mirror images of the same quasar whose light had been bent around the galaxy YGKOW G1 65 66 Frame dragging the idea that a rotating massive object should twist spacetime around it was confirmed by Gravity Probe B results in 2011 67 68 In 2015 the LIGO observatory detected faint gravitational waves the existence of which had been predicted by general relativity Scientists believe that the waves emanated from a black hole merger that occurred 1 5 billion light years away 69 SpecificsEarth s gravity An initially stationary object that is allowed to fall freely under gravity drops a distance that is proportional to the square of the elapsed time This image spans half a second and was captured at 20 flashes per second Main article Gravity of Earth Every planetary body including the Earth is surrounded by its own gravitational field which can be conceptualized with Newtonian physics as exerting an attractive force on all objects Assuming a spherically symmetrical planet the strength of this field at any given point above the surface is proportional to the planetary body s mass and inversely proportional to the square of the distance from the center of the body If an object with comparable mass to that of the Earth were to fall towards it then the corresponding acceleration of the Earth would be observable The strength of the gravitational field is numerically equal to the acceleration of objects under its influence 70 The rate of acceleration of falling objects near the Earth s surface varies very slightly depending on latitude surface features such as mountains and ridges and perhaps unusually high or low sub surface densities 71 For purposes of weights and measures a standard gravity value is defined by the International Bureau of Weights and Measures under the International System of Units SI The force of gravity on Earth is the resultant vector sum of two forces 72 a The gravitational attraction in accordance with Newton s universal law of gravitation and b the centrifugal force which results from the choice of an earthbound rotating frame of reference The force of gravity is weakest at the equator because of the centrifugal force caused by the Earth s rotation and because points on the equator are furthest from the center of the Earth The force of gravity varies with latitude and increases from about 9 780 m s2 at the Equator to about 9 832 m s2 at the poles citation needed Canada s Hudson Bay has less gravity than any place on Earth 73 Origin The earliest gravity possibly in the form of quantum gravity supergravity or a gravitational singularity along with ordinary space and time developed during the Planck epoch up to 10 43 seconds after the birth of the Universe possibly from a primeval state such as a false vacuum quantum vacuum or virtual particle in a currently unknown manner 4 Gravitational radiation The LIGO Hanford Observatory located in Washington United States where gravitational waves were first observed in September 2015 Main article Gravitational wave General relativity predicts that energy can be transported out of a system through gravitational radiation The first indirect evidence for gravitational radiation was through measurements of the Hulse Taylor binary in 1973 This system consists of a pulsar and neutron star in orbit around one another Its orbital period has decreased since its initial discovery due to a loss of energy which is consistent for the amount of energy loss due to gravitational radiation This research was awarded the Nobel Prize in Physics in 1993 citation needed The first direct evidence for gravitational radiation was measured on 14 September 2015 by the LIGO detectors The gravitational waves emitted during the collision of two black holes 1 3 billion light years from Earth were measured 74 75 This observation confirms the theoretical predictions of Einstein and others that such waves exist It also opens the way for practical observation and understanding of the nature of gravity and events in the Universe including the Big Bang 76 Neutron star and black hole formation also create detectable amounts of gravitational radiation 77 This research was awarded the Nobel Prize in Physics in 2017 78 Speed of gravity Main article Speed of gravity In December 2012 a research team in China announced that it had produced measurements of the phase lag of Earth tides during full and new moons which seem to prove that the speed of gravity is equal to the speed of light 79 This means that if the Sun suddenly disappeared the Earth would keep orbiting the vacant point normally for 8 minutes which is the time light takes to travel that distance The team s findings were released in Science Bulletin in February 2013 80 In October 2017 the LIGO and Virgo detectors received gravitational wave signals within 2 seconds of gamma ray satellites and optical telescopes seeing signals from the same direction This confirmed that the speed of gravitational waves was the same as the speed of light 81 Anomalies and discrepanciesNot to be confused with Gravity anomaly There are some observations that are not adequately accounted for which may point to the need for better theories of gravity or perhaps be explained in other ways Rotation curve of a typical spiral galaxy predicted A and observed B The discrepancy between the curves is attributed to dark matter Extra fast stars Stars in galaxies follow a distribution of velocities where stars on the outskirts are moving faster than they should according to the observed distributions of normal matter Galaxies within galaxy clusters show a similar pattern Dark matter which would interact through gravitation but not electromagnetically would account for the discrepancy Various modifications to Newtonian dynamics have also been proposed Flyby anomaly Various spacecraft have experienced greater acceleration than expected during gravity assist maneuvers Accelerating expansion The metric expansion of space seems to be speeding up Dark energy has been proposed to explain this A recent alternative explanation is that the geometry of space is not homogeneous due to clusters of galaxies and that when the data are reinterpreted to take this into account the expansion is not speeding up after all 82 however this conclusion is disputed 83 Anomalous increase of the astronomical unit Recent measurements indicate that planetary orbits are widening faster than if this were solely through the Sun losing mass by radiating energy Extra energetic photons Photons travelling through galaxy clusters should gain energy and then lose it again on the way out The accelerating expansion of the Universe should stop the photons returning all the energy but even taking this into account photons from the cosmic microwave background radiation gain twice as much energy as expected This may indicate that gravity falls off faster than inverse squared at certain distance scales 84 Extra massive hydrogen clouds The spectral lines of the Lyman alpha forest suggest that hydrogen clouds are more clumped together at certain scales than expected and like dark flow may indicate that gravity falls off slower than inverse squared at certain distance scales 84 Alternative theoriesMain article Alternatives to general relativity Historical alternative theories Aristotelian theory of gravity Le Sage s theory of gravitation 1784 also called LeSage gravity but originally proposed by Fatio and further elaborated by Georges Louis Le Sage based on a fluid based explanation where a light gas fills the entire Universe Ritz s theory of gravitation Ann Chem Phys 13 145 1908 pp 267 271 Weber Gauss electrodynamics applied to gravitation Classical advancement of perihelia Nordstrom s theory of gravitation 1912 1913 an early competitor of general relativity Kaluza Klein theory 1921 Whitehead s theory of gravitation 1922 another early competitor of general relativity Modern alternative theories Brans Dicke theory of gravity 1961 85 Induced gravity 1967 a proposal by Andrei Sakharov according to which general relativity might arise from quantum field theories of matter String theory late 1960s ƒ R gravity 1970 Horndeski theory 1974 86 Supergravity 1976 In the modified Newtonian dynamics MOND 1981 Mordehai Milgrom proposes a modification of Newton s second law of motion for small accelerations 87 The self creation cosmology theory of gravity 1982 by G A Barber in which the Brans Dicke theory is modified to allow mass creation Loop quantum gravity 1988 by Carlo Rovelli Lee Smolin and Abhay Ashtekar Nonsymmetric gravitational theory NGT 1994 by John Moffat Tensor vector scalar gravity TeVeS 2004 a relativistic modification of MOND by Jacob Bekenstein Chameleon theory 2004 by Justin Khoury and Amanda Weltman Pressuron theory 2013 by Olivier Minazzoli and Aurelien Hees Conformal 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