2023/08/18

Cosmology - Wikipedia

Cosmology - Wikipedia

Cosmology

From Wikipedia, the free encyclopedia
The Hubble eXtreme Deep Field (XDF) was completed in September 2012 and shows the farthest galaxies ever photographed at that time. Except for the few stars in the foreground (which are bright and easily recognizable because only they have diffraction spikes), every speck of light in the photo is an individual galaxy, some of them as old as 13.2 billion years; the observable universe is estimated to contain more than 2 trillion galaxies.[1]

Cosmology (from Ancient Greek κόσμος (kósmos) 'world', and -λογία (-logía) 'study of') is a branch of physics and metaphysics dealing with the nature of the universe. The term cosmology was first used in English in 1656 in Thomas Blount's Glossographia,[2] and in 1731 taken up in Latin by German philosopher Christian Wolff, in Cosmologia Generalis.[3] Religious or mythological cosmology is a body of beliefs based on mythologicalreligious, and esoteric literature and traditions of creation myths and eschatology. In the science of astronomy, cosmology is concerned with the study of the chronology of the universe.

Physical cosmology is the study of the observable universe's origin, its large-scale structures and dynamics, and the ultimate fate of the universe, including the laws of science that govern these areas.[4] It is investigated by scientists, including astronomers and physicists, as well as philosophers, such as metaphysiciansphilosophers of physics, and philosophers of space and time. Because of this shared scope with philosophytheories in physical cosmology may include both scientific and non-scientific propositions and may depend upon assumptions that cannot be tested. Physical cosmology is a sub-branch of astronomy that is concerned with the universe as a whole. Modern physical cosmology is dominated by the Big Bang Theory which attempts to bring together observational astronomy and particle physics;[5][6] more specifically, a standard parameterization of the Big Bang with dark matter and dark energy, known as the Lambda-CDM model.

Theoretical astrophysicist David N. Spergel has described cosmology as a "historical science" because "when we look out in space, we look back in time" due to the finite nature of the speed of light.[7]

Disciplines[edit]

Physics and Astrophysics have played central roles in shaping our understanding of the universe through scientific observation and experiment. Physical cosmology was shaped through both mathematics and observation in an analysis of the whole universe. The universe is generally understood to have begun with the Big Bang, followed almost instantaneously by cosmic inflation, an expansion of space from which the universe is thought to have emerged 13.799 ± 0.021 billion years ago.[8] Cosmogony studies the origin of the universe, and cosmography maps the features of the universe.

In Diderot's Encyclopédie, cosmology is broken down into uranology (the science of the heavens), aerology (the science of the air), geology (the science of the continents), and hydrology (the science of waters).[9]

Metaphysical cosmology has also been described as the placing of humans in the universe in relationship to all other entities. This is exemplified by Marcus Aurelius's observation that a man's place in that relationship: "He who does not know what the world is does not know where he is, and he who does not know for what purpose the world exists, does not know who he is, nor what the world is."[10]

Discoveries[edit]

Physical cosmology[edit]

Physical cosmology is the branch of physics and astrophysics that deals with the study of the physical origins and evolution of the universe. It also includes the study of the nature of the universe on a large scale. In its earliest form, it was what is now known as "celestial mechanics", the study of the heavens. Greek philosophers Aristarchus of SamosAristotle, and Ptolemy proposed different cosmological theories. The geocentric Ptolemaic system was the prevailing theory until the 16th century when Nicolaus Copernicus, and subsequently Johannes Kepler and Galileo Galilei, proposed a heliocentric system. This is one of the most famous examples of epistemological rupture in physical cosmology.

Isaac Newton's Principia Mathematica, published in 1687, was the first description of the law of universal gravitation. It provided a physical mechanism for Kepler's laws and also allowed the anomalies in previous systems, caused by gravitational interaction between the planets, to be resolved. A fundamental difference between Newton's cosmology and those preceding it was the Copernican principle—that the bodies on Earth obey the same physical laws as all celestial bodies. This was a crucial philosophical advance in physical cosmology.

Modern scientific cosmology is widely considered to have begun in 1917 with Albert Einstein's publication of his final modification of general relativity in the paper "Cosmological Considerations of the General Theory of Relativity"[11] (although this paper was not widely available outside of Germany until the end of World War I). General relativity prompted cosmogonists such as Willem de SitterKarl Schwarzschild, and Arthur Eddington to explore its astronomical ramifications, which enhanced the ability of astronomers to study very distant objects. Physicists began changing the assumption that the universe was static and unchanging. In 1922, Alexander Friedmann introduced the idea of an expanding universe that contained moving matter.

In parallel to this dynamic approach to cosmology, one long-standing debate about the structure of the cosmos was coming to a climax - the Great Debate (1917 to 1922) - with early cosmologists such as Heber Curtis and Ernst Öpik determining that some nebulae seen in telescopes were separate galaxies far distant from our own.[12] While Heber Curtis argued for the idea that spiral nebulae were star systems in their own right as island universes, Mount Wilson astronomer Harlow Shapley championed the model of a cosmos made up of the Milky Way star system only. This difference of ideas came to a climax with the organization of the Great Debate on 26 April 1920 at the meeting of the U.S. National Academy of Sciences in Washington, D.C. The debate was resolved when Edwin Hubble detected Cepheid Variables in the Andromeda Galaxy in 1923 and 1924.[13][14] Their distance established spiral nebulae well beyond the edge of the Milky Way.

Subsequent modelling of the universe explored the possibility that the cosmological constant, introduced by Einstein in his 1917 paper, may result in an expanding universe, depending on its value. Thus the Big Bang model was proposed by the Belgian priest Georges Lemaître in 1927[15] which was subsequently corroborated by Edwin Hubble's discovery of the redshift in 1929[16] and later by the discovery of the cosmic microwave background radiation by Arno Penzias and Robert Woodrow Wilson in 1964.[17] These findings were a first step to rule out some of many alternative cosmologies.

Since around 1990, several dramatic advances in observational cosmology have transformed cosmology from a largely speculative science into a predictive science with precise agreement between theory and observation. These advances include observations of the microwave background from the COBE,[18] WMAP[19] and Planck satellites,[20] large new galaxy redshift surveys including 2dfGRS[21] and SDSS,[22] and observations of distant supernovae and gravitational lensing. These observations matched the predictions of the cosmic inflation theory, a modified Big Bang theory, and the specific version known as the Lambda-CDM model. This has led many to refer to modern times as the "golden age of cosmology".[23]

In 2014, the BICEP2 collaboration claimed that they had detected the imprint of gravitational waves in the cosmic microwave background. However, this result was later found to be spurious: the supposed evidence of gravitational waves was in fact due to interstellar dust.[24][25]

On 1 December 2014, at the Planck 2014 meeting in FerraraItaly, astronomers reported that the universe is 13.8 billion years old and composed of 4.9% atomic matter, 26.6% dark matter and 68.5% dark energy.[26]

Religious or mythological cosmology[edit]

Religious or mythological cosmology is a body of beliefs based on mythologicalreligious, and esoteric literature and traditions of creation and eschatology. Creation myths are found in most religions, and are typically split into five different classifications, based on a system created by Mircea Eliade and his colleague Charles Long.

  • Types of Creation Myths based on similar motifs:
    • Creation ex nihilo in which the creation is through the thought, word, dream or bodily secretions of a divine being.
    • Earth diver creation in which a diver, usually a bird or amphibian sent by a creator, plunges to the seabed through a primordial ocean to bring up sand or mud which develops into a terrestrial world.
    • Emergence myths in which progenitors pass through a series of worlds and metamorphoses until reaching the present world.
    • Creation by the dismemberment of a primordial being.
    • Creation by the splitting or ordering of a primordial unity such as the cracking of a cosmic egg or a bringing order from chaos.[27]

Philosophy[edit]

Representation of the observable universe on a logarithmic scale. Distance from the Sun increases from center to edge. Planets and other celestial bodies were enlarged to appreciate their shapes.

Cosmology deals with the world as the totality of space, time and all phenomena. Historically, it has had quite a broad scope, and in many cases was found in religion.[28] Some questions about the Universe are beyond the scope of scientific inquiry, but may still be interrogated through appeals to other philosophical approaches like dialectics. Some questions that are included in extra-scientific endeavors may include:[29][30]

  • What is the origin of the universe? What is its first cause (if any)? Is its existence necessary? (see monismpantheismemanationism and creationism)
  • What are the ultimate material components of the universe? (see mechanismdynamismhylomorphismatomism)
  • What is the ultimate reason (if any) for the existence of the universe? Does the cosmos have a purpose? (see teleology)
  • Does the existence of consciousness have a role in the existence of reality? How do we know what we know about the totality of the cosmos? Does cosmological reasoning reveal metaphysical truths? (see epistemology)

Historical cosmologies[edit]

NameAuthor and dateClassificationRemarks
Hindu cosmologyRigveda (c. 1700–1100 BCE)Cyclical or oscillating, Infinite in timePrimal matter remains manifest for 311.04 trillion years and unmanifest for an equal length. The universe remains manifest for 4.32 billion years and unmanifest for an equal length. Innumerable universes exist simultaneously. These cycles have and will last forever, driven by desires.
Jain cosmologyJain Agamas (written around 500 CE as per the teachings of Mahavira 599–527 BCE)Cyclical or oscillating, eternal and finiteJain cosmology considers the loka, or universe, as an uncreated entity, existing since infinity, the shape of the universe as similar to a man standing with legs apart and arm resting on his waist. This Universe, according to Jainism, is broad at the top, narrow at the middle and once again becomes broad at the bottom.
Babylonian cosmologyBabylonian literature (c. 2300–500 BCE)Flat earth floating in infinite "waters of chaos"The Earth and the Heavens form a unit within infinite "waters of chaos"; the earth is flat and circular, and a solid dome (the "firmament") keeps out the outer "chaos"-ocean.
Eleatic cosmologyParmenides (c. 515 BCE)Finite and spherical in extentThe Universe is unchanging, uniform, perfect, necessary, timeless, and neither generated nor perishable. Void is impossible. Plurality and change are products of epistemic ignorance derived from sense experience. Temporal and spatial limits are arbitrary and relative to the Parmenidean whole.
Samkhya Cosmic EvolutionKapila (6th century BCE), pupil AsuriPrakriti (Matter) and Purusha (Consiouness) RelationPrakriti (Matter) is the source of the world of becoming. It is pure potentiality that evolves itself successively into twenty four tattvas or principles. The evolution itself is possible because Prakriti is always in a state of tension among its constituent strands known as gunas (Sattva (lightness or purity), Rajas (passion or activity), and Tamas (inertia or heaviness)). The cause and effect theory of Sankhya is called Satkaarya-vaada (theory of existent causes), and holds that nothing can really be created from or destroyed into nothingness—all evolution is simply the transformation of primal Nature from one form to another.[citation needed]
Biblical cosmologyGenesis creation narrativeEarth floating in infinite "waters of chaos"The Earth and the Heavens form a unit within infinite "waters of chaos"; the "firmament" keeps out the outer "chaos"-ocean.
Anaximander's modelAnaximander (c. 560 BCE)Geocentric, cylindrical Earth, infinite in extent, finite time; first purely mechanical modelThe Earth floats very still in the centre of the infinite, not supported by anything.[31] At the origin, after the separation of hot and cold, a ball of flame appeared that surrounded Earth like bark on a tree. This ball broke apart to form the rest of the Universe. It resembled a system of hollow concentric wheels, filled with fire, with the rims pierced by holes like those of a flute; no heavenly bodies as such, only light through the holes. Three wheels, in order outwards from Earth: stars (including planets), Moon and a large Sun.[32]
Atomist universeAnaxagoras (500–428 BCE) & later EpicurusInfinite in extentThe universe contains only two things: an infinite number of tiny seeds (atoms) and the void of infinite extent. All atoms are made of the same substance, but differ in size and shape. Objects are formed from atom aggregations and decay back into atoms. Incorporates Leucippus' principle of causality: "nothing happens at random; everything happens out of reason and necessity". The universe was not ruled by gods.[citation needed]
Pythagorean universePhilolaus (d. 390 BCE)Existence of a "Central Fire" at the center of the Universe.At the center of the Universe is a central fire, around which the Earth, Sun, Moon and planets revolve uniformly. The Sun revolves around the central fire once a year, the stars are immobile. The earth in its motion maintains the same hidden face towards the central fire, hence it is never seen. First known non-geocentric model of the Universe.[33]
De MundoPseudo-Aristotle (d. 250 BCE or between 350 and 200 BCE)The Universe is a system made up of heaven and earth and the elements which are contained in them.There are "five elements, situated in spheres in five regions, the less being in each case surrounded by the greater – namely, earth surrounded by water, water by air, air by fire, and fire by ether – make up the whole Universe."[34]
Stoic universeStoics (300 BCE – 200 CE)Island universeThe cosmos is finite and surrounded by an infinite void. It is in a state of flux, and pulsates in size and undergoes periodic upheavals and conflagrations.
Platonic universePlato (c. 360 BCE)Geocentric, complex cosmogony, finite extent, implied finite time, cyclicalStatic Earth at center, surrounded by heavenly bodies which move in perfect circles, arranged by the will of the demiurge[35] in order: Moon, Sun, planets and fixed stars.[36][37] Complex motions repeat every 'perfect' year.[38]
Eudoxus' modelEudoxus of Cnidus (c. 340 BCE) and later CallippusGeocentric, first geometric-mathematical modelThe heavenly bodies move as if they were attached to a number of Earth centered concentrical, invisible spheres, every of them rotating around its own and different axis and at different paces.[39] There are twenty-seven homocentric spheres with each sphere explaining a type of observable motion for each celestial object. Eudoxus emphasised that this is a purely mathematical construct of the model in the sense that the spheres of each celestial body do not exist, it just shows the possible positions of the bodies.[40]
Aristotelian universeAristotle (384–322 BCE)Geocentric (based on Eudoxus' model), static, steady state, finite extent, infinite timeStatic and spherical Earth is surrounded by 43 to 55 concentric celestial spheres, which are material and crystalline.[41] Universe exists unchanged throughout eternity. Contains a fifth element, called aether, that was added to the four classical elements.[42]
Aristarchean universeAristarchus (c. 280 BCE)HeliocentricEarth rotates daily on its axis and revolves annually about the Sun in a circular orbit. Sphere of fixed stars is centered about the Sun.[43]
Ptolemaic modelPtolemy (2nd century CE)Geocentric (based on Aristotelian universe)Universe orbits around a stationary Earth. Planets move in circular epicycles, each having a center that moved in a larger circular orbit (called an eccentric or a deferent) around a center-point near Earth. The use of equants added another level of complexity and allowed astronomers to predict the positions of the planets. The most successful universe model of all time, using the criterion of longevity. The Almagest (the Great System).
Capella's modelMartianus Capella (c. 420)Geocentric and HeliocentricThe Earth is at rest in the center of the universe and circled by the Moon, the Sun, three planets and the stars, while Mercury and Venus circle the Sun.[44]
Aryabhatan modelAryabhata (499)Geocentric or HeliocentricThe Earth rotates and the planets move in elliptical orbits around either the Earth or Sun; uncertain whether the model is geocentric or heliocentric due to planetary orbits given with respect to both the Earth and Sun.
Medieval universeMedieval philosophers (500–1200)Finite in timeA universe that is finite in time and has a beginning is proposed by the Christian philosopher John Philoponus, who argues against the ancient Greek notion of an infinite past. Logical arguments supporting a finite universe are developed by the early Muslim philosopher Al-Kindi, the Jewish philosopher Saadia Gaon, and the Muslim theologian Al-Ghazali.
Non-Parallel MultiverseBhagvata Puran(800–1000)Multiverse, Non ParallelInnumerable universes is comparable to the multiverse theory, except nonparallel where each universe is different and individual jiva-atmas (embodied souls) exist in exactly one universe at a time. All universes manifest from the same matter, and so they all follow parallel time cycles, manifesting and unmanifesting at the same time.[45]
Multiversal cosmologyFakhr al-Din al-Razi (1149–1209)Multiverse, multiple worlds and universesThere exists an infinite outer space beyond the known world, and God has the power to fill the vacuum with an infinite number of universes.
Maragha modelsMaragha school (1259–1528)GeocentricVarious modifications to Ptolemaic model and Aristotelian universe, including rejection of equant and eccentrics at Maragheh observatory, and introduction of Tusi-couple by Al-Tusi. Alternative models later proposed, including the first accurate lunar model by Ibn al-Shatir, a model rejecting stationary Earth in favour of Earth's rotation by Ali Kuşçu, and planetary model incorporating "circular inertia" by Al-Birjandi.
Nilakanthan modelNilakantha Somayaji (1444–1544)Geocentric and heliocentricA universe in which the planets orbit the Sun, which orbits the Earth; similar to the later Tychonic system.
Copernican universeNicolaus Copernicus (1473–1543)Heliocentric with circular planetary orbits, finite extentFirst described in De revolutionibus orbium coelestium. The Sun is in the center of the universe, planets including Earth orbit the Sun, but the Moon orbits the Earth. The universe is limited by the sphere of the fixed stars.
Tychonic systemTycho Brahe (1546–1601)Geocentric and HeliocentricA universe in which the planets orbit the Sun and the Sun orbits the Earth, similar to the earlier Nilakanthan model.
Bruno's cosmologyGiordano Bruno (1548–1600)Infinite extent, infinite time, homogeneous, isotropic, non-hierarchicalRejects the idea of a hierarchical universe. Earth and Sun have no special properties in comparison with the other heavenly bodies. The void between the stars is filled with aether, and matter is composed of the same four elements (water, earth, fire, and air), and is atomistic, animistic and intelligent.
De MagneteWilliam Gilbert (1544–1603)Heliocentric, indefinitely extendedCopernican heliocentrism, but he rejects the idea of a limiting sphere of the fixed stars for which no proof has been offered.[46]
KeplerianJohannes Kepler (1571–1630)Heliocentric with elliptical planetary orbitsKepler's discoveries, marrying mathematics and physics, provided the foundation for our present conception of the Solar system, but distant stars were still seen as objects in a thin, fixed celestial sphere.
Static NewtonianIsaac Newton (1642–1727)Static (evolving), steady state, infiniteEvery particle in the universe attracts every other particle. Matter on the large scale is uniformly distributed. Gravitationally balanced but unstable.
Cartesian Vortex universeRené Descartes, 17th centuryStatic (evolving), steady state, infiniteSystem of huge swirling whirlpools of aethereal or fine matter produces what we would call gravitational effects. But his vacuum was not empty; all space was filled with matter.
Hierarchical universeImmanuel KantJohann Lambert, 18th centuryStatic (evolving), steady state, infiniteMatter is clustered on ever larger scales of hierarchy. Matter is endlessly recycled.
Einstein Universe with a cosmological constantAlbert Einstein, 1917Static (nominally). Bounded (finite)"Matter without motion". Contains uniformly distributed matter. Uniformly curved spherical space; based on Riemann's hypersphere. Curvature is set equal to Λ. In effect Λ is equivalent to a repulsive force which counteracts gravity. Unstable.
De Sitter universeWillem de Sitter, 1917Expanding flat space.

Steady state. Λ > 0

"Motion without matter." Only apparently static. Based on Einstein's general relativity. Space expands with constant accelerationScale factor increases exponentially (constant inflation).
MacMillan universeWilliam Duncan MacMillan 1920sStatic and steady stateNew matter is created from radiation; starlight perpetually recycled into new matter particles.
Friedmann universe, spherical spaceAlexander Friedmann 1922Spherical expanding space.

k = +1 ; no Λ

Positive curvature. Curvature constant k = +1

Expands then recollapsesSpatially closed (finite).

Friedmann universe, hyperbolic spaceAlexander Friedmann, 1924Hyperbolic expanding space.

k = −1 ; no Λ

Negative curvature. Said to be infinite (but ambiguous). Unbounded. Expands forever.
Dirac large numbers hypothesisPaul Dirac 1930sExpandingDemands a large variation in G, which decreases with time. Gravity weakens as universe evolves.
Friedmann zero-curvatureEinstein and De Sitter, 1932Expanding flat space

k = 0 ; Λ = 0 Critical density

Curvature constant k = 0. Said to be infinite (but ambiguous). "Unbounded cosmos of limited extent". Expands forever. "Simplest" of all known universes. Named after but not considered by Friedmann. Has a deceleration term q = 1/2, which means that its expansion rate slows down.
The original Big Bang (Friedmann-Lemaître)Georges Lemaître 1927–29Expansion

Λ > 0 ; Λ > |Gravity|

Λ is positive and has a magnitude greater than gravity. Universe has initial high-density state ("primeval atom"). Followed by a two-stage expansion. Λ is used to destabilize the universe. (Lemaître is considered the father of the Big Bang model.)
Oscillating universe (Friedmann-Einstein)Favored by Friedmann, 1920sExpanding and contracting in cyclesTime is endless and beginningless; thus avoids the beginning-of-time paradox. Perpetual cycles of Big Bang followed by Big Crunch. (Einstein's first choice after he rejected his 1917 model.)
Eddington universeArthur Eddington 1930First static then expandsStatic Einstein 1917 universe with its instability disturbed into expansion mode; with relentless matter dilution becomes a De Sitter universe. Λ dominates gravity.
Milne universe of kinematic relativityEdward Milne, 1933, 1935;

William H. McCrea, 1930s

Kinematic expansion without space expansionRejects general relativity and the expanding space paradigm. Gravity not included as initial assumption. Obeys cosmological principle and special relativity; consists of a finite spherical cloud of particles (or galaxies) that expands within an infinite and otherwise empty flat space. It has a center and a cosmic edge (surface of the particle cloud) that expands at light speed. Explanation of gravity was elaborate and unconvincing.
Friedmann–Lemaître–Robertson–Walker class of modelsHoward RobertsonArthur Walker, 1935Uniformly expandingClass of universes that are homogeneous and isotropic. Spacetime separates into uniformly curved space and cosmic time common to all co-moving observers. The formulation system is now known as the FLRW or Robertson–Walker metrics of cosmic time and curved space.
Steady-stateHermann BondiThomas Gold, 1948Expanding, steady state, infiniteMatter creation rate maintains constant density. Continuous creation out of nothing from nowhere. Exponential expansion. Deceleration term q = −1.
Steady-stateFred Hoyle 1948Expanding, steady state; but unstableMatter creation rate maintains constant density. But since matter creation rate must be exactly balanced with the space expansion rate the system is unstable.
AmbiplasmaHannes Alfvén 1965 Oskar KleinCellular universe, expanding by means of matter–antimatter annihilationBased on the concept of plasma cosmology. The universe is viewed as "meta-galaxies" divided by double layers and thus a bubble-like nature. Other universes are formed from other bubbles. Ongoing cosmic matter-antimatter annihilations keep the bubbles separated and moving apart preventing them from interacting.
Brans–Dicke theoryCarl H. BransRobert H. DickeExpandingBased on Mach's principleG varies with time as universe expands. "But nobody is quite sure what Mach's principle actually means."[citation needed]
Cosmic inflationAlan Guth 1980Big Bang modified to solve horizon and flatness problemsBased on the concept of hot inflation. The universe is viewed as a multiple quantum flux – hence its bubble-like nature. Other universes are formed from other bubbles. Ongoing cosmic expansion kept the bubbles separated and moving apart.
Eternal inflation (a multiple universe model)Andreï Linde, 1983Big Bang with cosmic inflationMultiverse based on the concept of cold inflation, in which inflationary events occur at random each with independent initial conditions; some expand into bubble universes supposedly like our entire cosmos. Bubbles nucleate in a spacetime foam.
Cyclic modelPaul SteinhardtNeil Turok 2002Expanding and contracting in cycles; M-theory.Two parallel orbifold planes or M-branes collide periodically in a higher-dimensional space. With quintessence or dark energy.
Cyclic modelLauris Baum; Paul Frampton 2007Solution of Tolman's entropy problemPhantom dark energy fragments universe into large number of disconnected patches. Our patch contracts containing only dark energy with zero entropy.

Table notes: the term "static" simply means not expanding and not contracting. Symbol G represents Newton's gravitational constant; Λ (Lambda) is the cosmological constant.

See also[edit]

References[edit]

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  10. ^ The thoughts of Marcus Aurelius Antoninus viii. 52.
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  23. ^ Alan Guth is reported to have made this very claim in an Edge Foundation interview EDGE Archived 11 April 2016 at the Wayback Machine
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  27. ^ Leonard & McClure 2004, pp. 32–33
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  31. ^ Aristotle, On the Heavens, ii, 13
  32. ^ Most of Anaximander's model of the Universe comes from pseudo-Plutarch (II, 20–28):
    "[The Sun] is a circle twenty-eight times as big as the Earth, with the outline similar to that of a fire-filled chariot wheel, on which appears a mouth in certain places and through which it exposes its fire, as through the hole on a flute. [...] the Sun is equal to the Earth, but the circle on which it breathes and on which it's borne is twenty-seven times as big as the whole earth. [...] [The eclipse] is when the mouth from which comes the fire heat is closed. [...] [The Moon] is a circle nineteen times as big as the whole earth, all filled with fire, like that of the Sun".
  33. ^ Carl B. Boyer (1968), A History of Mathematics. Wiley. ISBN 0471543977. p. 54.
  34. ^ Aristotle (1914). Forster, E. S.; Dobson, J. F. (eds.). De Mundo. Oxford University Press. 393a.
  35. ^ "The components from which he made the soul and the way in which he made it were as follows: In between the Being that is indivisible and always changeless, and the one that is divisible and comes to be in the corporeal realm, he mixed a third, intermediate form of being, derived from the other two. Similarly, he made a mixture of the Same, and then one of the Different, in between their indivisible and their corporeal, divisible counterparts. And he took the three mixtures and mixed them together to make a uniform mixture, forcing the Different, which was hard to mix, into conformity with the Same. Now when he had mixed these two with Being, and from the three had made a single mixture, he redivided the whole mixture into as many parts as his task required, each part remaining a mixture of the Same, the Different and Being." (35a-b), translation Donald J. Zeyl
  36. ^ Plato, Timaeus, 36c
  37. ^ Plato, Timaeus, 36d
  38. ^ Plato, Timaeus, 39d
  39. ^ Yavetz, Ido (February 1998). "On the Homocentric Spheres of Eudoxus". Archive for History of Exact Sciences52 (3): 222–225. Bibcode:1998AHES...52..222Ydoi:10.1007/s004070050017JSTOR 41134047S2CID 121186044.
  40. ^ Crowe, Michael (2001). Theories of the World from Antiquity to the Copernican Revolution. Mineola, NY: Dover. p. 23. ISBN 0-486-41444-2.
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  43. ^ Hirshfeld, Alan W. (2004). "The Triangles of Aristarchus"The Mathematics Teacher97 (4): 228–231. doi:10.5951/MT.97.4.0228ISSN 0025-5769JSTOR 20871578.
  44. ^ Bruce S. Eastwood, Ordering the Heavens: Roman Astronomy and Cosmology in the Carolingian Renaissance (Leiden: Brill, 2007), pp. 238-9.
  45. ^ Mirabello, Mark (15 September 2016). A Traveler's Guide to the Afterlife: Traditions and Beliefs on Death, Dying, and What Lies Beyond. Simon and Schuster. p. 23. ISBN 978-1-62055-598-9.
  46. ^ Gilbert, William (1893). "Book 6, Chapter III". De Magnete. Translated by Mottelay, P. Fleury. (Facsimile). New York: Dover Publications. ISBN 0-486-26761-X.

Sources[edit]

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