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Timeline of knowledge about galaxies, clusters of galaxies, and large-scale structure
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<h2 id="pre-20th-century">Pre-20th century</h2> <ul><li>5th century BC – <a href="/facts/Democritus/yTzsod3v">Democritus</a> proposes that the bright band in the night sky known as the <a href="/facts/Milky_Way/ulF6lccN">Milky Way</a> might consist of <a href="/facts/Star/PFbd6ICx">stars</a>.</li> <li>4th century BC – <a href="/facts/Aristotle/U2bDlBFW">Aristotle</a> believes the Milky Way to be caused by "the ignition of the fiery exhalation of some stars which were large, numerous and close together" and that the "ignition takes place in the upper part of the <a href="/facts/Atmosphere/oUpLaGRF">atmosphere</a>, in the <a href="/facts/Sublunary_sphere/ttYhpxtx">region of the world which is continuous with the heavenly motions</a>".<a class="footnote-ref" id="fnref:1" href="#fn:1"><sup>1</sup></a></li> <li>964 – <a href="/facts/Abd_al-Rahman_al-Sufi/qzc2hHfl">Abd al-Rahman al-Sufi</a> (Azophi), a <a href="/facts/Astronomy_in_medieval_Islam/hw8HxDHz">Persian astronomer</a>, makes the first recorded observations of the <a href="/facts/Andromeda_Galaxy/MjmSLV6m">Andromeda Galaxy</a><a class="footnote-ref" id="fnref:2" href="#fn:2"><sup>2</sup></a> and the <a href="/facts/Large_Magellanic_Cloud/7VYAehNa">Large Magellanic Cloud</a><a class="footnote-ref" id="fnref:3" href="#fn:3"><sup>3</sup></a><a class="footnote-ref" id="fnref:4" href="#fn:4"><sup>4</sup></a> in his <i><a href="/facts/Book_of_Fixed_Stars/8aMMc7EN">Book of Fixed Stars</a></i>, and which are the first galaxies other than the Milky Way to be recorded.</li> <li>11th century – <a href="/facts/Al-Biruni/4XbTzrYl">Al-Biruni</a>, another Persian astronomer, describes the <a href="/facts/Milky_Way/ulF6lccN">Milky Way</a> galaxy as a collection of fragments of numerous <a href="/facts/Nebula/hG6coklY">nebulous</a> stars.<a class="footnote-ref" id="fnref:5" href="#fn:5"><sup>5</sup></a></li> <li>11th century – <a href="/facts/Alhazen/Q5H9hm4J">Alhazen</a> (Ibn al-Haytham), an <a href="/facts/Islamic_astronomy/hw8HxDHz">Arabian astronomer</a>, refutes Aristotle's theory on the Milky Way by making the first attempt at observing and measuring the Milky Way's <a href="/facts/Parallax/Gu8W21LP">parallax</a>,<a class="footnote-ref" id="fnref:6" href="#fn:6"><sup>6</sup></a> and he thus "determined that because the Milky Way had no parallax, it was very remote from the Earth and did not belong to the atmosphere".<a class="footnote-ref" id="fnref:7" href="#fn:7"><sup>7</sup></a></li> <li>12th century – <a href="/facts/Avempace/gG1Iq21r">Avempace</a> (Ibn Bajjah) of <a href="/facts/Al-Andalus/JTNmWTzP">Islamic Spain</a> proposes the Milky Way to be made up of many stars but that it appears to be a continuous image due to the effect of <a href="/facts/Refraction/S8kvSKzM">refraction</a> in the <a href="/facts/Earth%2527s_atmosphere/FV97Am25">Earth's atmosphere</a>.<a class="footnote-ref" id="fnref:8" href="#fn:8"><sup>8</sup></a></li> <li>14th century – <a href="/facts/Ibn_Qayyim_al-Jawziyya/XdpWwkPM">Ibn Qayyim al-Jawziyya</a> of <a href="/facts/Syria/7pDXGzq8">Syria</a> proposes the Milky Way galaxy to be "a myriad of tiny stars packed together in the sphere of the fixed stars", and that these stars are larger than <a href="/facts/Planet/rbPjE6Bx">planets</a>.<a class="footnote-ref" id="fnref:9" href="#fn:9"><sup>9</sup></a></li> <li>1521 – <a href="/facts/Ferdinand_Magellan/DgNLv567">Ferdinand Magellan</a> observes the <a href="/facts/Magellanic_Clouds/WEspxUJl">Magellanic Clouds</a> during his circumnavigating expedition.<a class="footnote-ref" id="fnref:10" href="#fn:10"><sup>10</sup></a></li> <li>1610 – <a href="/facts/Galileo_Galilei/98VT2z3v">Galileo Galilei</a> uses a <a href="/facts/Telescope/BDwYahhR">telescope</a> to determine that the bright band on the <a href="/facts/Sky/wwvQ84J1">sky</a>, the "<a href="/facts/Milky_Way/ulF6lccN">Milky Way</a>", is composed of many faint stars.</li> <li>1612 – Simon Marius using a moderate telescope observes Andromeda and describes as a "flame seen through horn".<a class="footnote-ref" id="fnref:11" href="#fn:11"><sup>11</sup></a></li> <li>1750 – <a href="/facts/Thomas_Wright_(astronomer)/zlfrX17L">Thomas Wright</a> discusses <a href="/facts/Galaxy/zCyUvEf7">galaxies</a> and the flattened shape of the Milky Way and speculates nebulae as separate.<a class="footnote-ref" id="fnref:12" href="#fn:12"><sup>12</sup></a></li> <li>1755 – <a href="/facts/Immanuel_Kant/vIxjdy6I">Immanuel Kant</a> drawing on Wright's work conjectures that our galaxy is a rotating disk of stars held together by <a href="/facts/Gravity/bqAN7DdQ">gravity</a>, and that the <a href="/facts/Nebula/hG6coklY">nebulae</a> are separate such galaxies; he calls them <i><a href="/facts/Island_universe/zCyUvEf7">Island Universes</a></i>.</li> <li>1774 – <a href="/facts/Charles_Messier/dTokW7Yy">Charles Messier</a> releases a preliminary list of 45 <a href="/facts/Messier_object/YKz2MxzQ">Messier objects</a>, three of which turn out to be the galaxies including <a href="/facts/Andromeda_Galaxy/MjmSLV6m">Andromeda</a> and <a href="/facts/Triangulum_Galaxy/etLCCGhP">Triangulum</a>. By 1781 the final published list grows to 103 objects, 34 of which turn out to be galaxies.</li> <li>1785 – <a href="/facts/William_Herschel/SsruaBvq">William Herschel</a> carried the first attempt to describe the shape of the Milky Way and the position of the Sun in it by carefully counting the number of stars in different regions of the sky. He produced a diagram of the shape of the galaxy with the <a href="/facts/Solar_System/QIcLSazQ">Solar System</a> close to the center.</li> <li>1845 – <a href="/facts/William_Parsons%2c_3rd_Earl_of_Rosse/bPQ37rMF">Lord Rosse</a> discovers a nebula with a distinct spiral shape.</li></ul> <h2 id="early-20th-century">Early 20th century</h2> <ul><li>1912 – <a href="/facts/Vesto_Slipher/ewBeHwIC">Vesto Slipher's</a> spectrographic studies of spiral nebulae find high <a href="/facts/Doppler_shift/bzrK1BKf">Doppler shifts</a> indicating recessional velocity.</li> <li>1917 – <a href="/facts/Heber_Curtis/KaGog5aI">Heber Curtis</a> finds novae in <a href="/facts/Andromeda_(constellation)/PN2eI1WI">Andromeda</a> Nebula <a href="/facts/Andromeda_Galaxy/MjmSLV6m">M31</a> were ten <a href="/facts/Magnitude_(astronomy)/f4FbscJu">magnitudes</a> fainter than normal, giving a distance estimate of 150,000 <a href="/facts/Parsec/SwSsk57J">parsecs</a> supporting the "island universes" or independent galaxies hypothesis for spiral nebulae.</li> <li>1918 – <a href="/facts/Harlow_Shapley/EBHMWFuP">Harlow Shapley</a> demonstrates that <a href="/facts/Globular_cluster/FL0EERJU">globular clusters</a> are arranged in a spheroid or halo whose center is not the Earth, and hypothesizes, correctly, that its center is the <a href="/facts/Galactic_Center/TI4MwWwM">Galactic Center</a> of the galaxy,</li> <li>26 April 1920 – Harlow Shapley and <a href="/facts/Heber_Curtis/KaGog5aI">Heber Curtis</a> <a href="/facts/Great_Debate_(astronomy)/aF4mJfJe">debate</a> whether Andromeda Nebula is within the Milky Way. Curtis notes dark lanes in Andromeda resembling the dust clouds in the Milky Way, as well as significant Doppler shift.</li> <li>1922 – <a href="/facts/Ernst_%25C3%2596pik/DYT6Pmpx">Ernst Öpik</a> distance determination supports Andromeda as extra-galactic object.</li> <li>1923 – <a href="/facts/Edwin_Hubble/fpX3JlbJ">Edwin Hubble</a> resolves the <a href="/facts/Great_Debate_(astronomy)/aF4mJfJe">Shapley–Curtis debate</a> by finding <a href="/facts/Cepheid_variable/WQXaAFmW">Cepheids</a> in the <a href="/facts/Andromeda_Galaxy/MjmSLV6m">Andromeda Galaxy</a>, definitively proving that there are other galaxies beyond the Milky Way.</li> <li>1930 – <a href="/facts/Robert_Trumpler/akR1f6lp">Robert Trumpler</a> uses <a href="/facts/Open_cluster/UodlJqcx">open cluster</a> observations to quantify the <a href="/facts/Absorption_(electromagnetic_radiation)/xBYKt7yS">absorption</a> of <a href="/facts/Light/jeofpMn4">light</a> by <a href="/facts/Interstellar_dust/Uy6hlL29">interstellar dust</a> in the <a href="/facts/Galactic_plane/4eaqfCIB">galactic plane</a>; this absorption had plagued earlier models of the Milky Way.</li> <li>1932 – <a href="/facts/Karl_Guthe_Jansky/E72Me0F6">Karl Guthe Jansky</a> discovers <a href="/facts/Radio_noise/hWt85Gyy">radio noise</a> from the center of the Milky Way.</li> <li>1933 – <a href="/facts/Fritz_Zwicky/E4S5dcmD">Fritz Zwicky</a> applies the <a href="/facts/Virial_theorem/w3qwDrkr">virial theorem</a> to the <a href="/facts/Coma_Cluster/k5Fw8qUH">Coma Cluster</a> and obtains evidence for unseen <a href="/facts/Mass/HHdc8XmF">mass</a>.</li> <li>1936 – Edwin Hubble introduces the spiral, barred spiral, elliptical, and irregular galaxy classifications.</li> <li>1939 – <a href="/facts/Grote_Reber/c7vQTuSR">Grote Reber</a> discovers the radio source <a href="/facts/Cygnus_A/wwmFp660">Cygnus A</a>.</li> <li>1943 – <a href="/facts/Carl_Keenan_Seyfert/R26NTpvt">Carl Keenan Seyfert</a> identifies six spiral galaxies with unusually broad <a href="/facts/Emission_line/HuI4Bj5f">emission lines</a>, named <a href="/facts/Seyfert_galaxy/N7T3SleM">Seyfert galaxies</a>.</li> <li>1949 – J. G. Bolton, G. J. Stanley, and O. B. Slee identify <a href="/facts/NGC_4486/x8Q1M5p4">NGC 4486</a> (<a href="/facts/Elliptical_galaxy_M87/x8Q1M5p4">M87</a>) and <a href="/facts/NGC_5128/gXJfrunq">NGC 5128</a> as extragalactic radio sources.</li></ul> <h2 id="mid-20th-century">Mid-20th century</h2> <ul><li>1953 – <a href="/facts/G%25C3%25A9rard_de_Vaucouleurs/4kTxWxAl">Gérard de Vaucouleurs</a> discovers that the galaxies within approximately 200 million <a href="/facts/Light-year/IGc5NdQb">light-years</a> of the <a href="/facts/Virgo_Cluster/dBsDKTzT">Virgo Cluster</a> are confined to a giant <a href="/facts/Supercluster/DIBrfG30">supercluster</a> disk.</li> <li>1954 – <a href="/facts/Walter_Baade/olu54Cof">Walter Baade</a> and <a href="/facts/Rudolph_Minkowski/b90G2T2F">Rudolph Minkowski</a> identify the extragalactic optical counterpart of the radio source Cygnus A.</li> <li>1959 – Hundreds of radio sources are detected by the <a href="/facts/Cambridge_Interferometer/GkxNP3Kw">Cambridge Interferometer</a> which produces the <a href="/facts/Third_Cambridge_Catalogue_of_Radio_Sources/T5zYFDIz">3C catalogue</a>. Many of these are later found to be distant quasars and radio galaxies.</li> <li>1960 – <a href="/facts/Thomas_Matthews_(astronomer)/4gIxyfu1">Thomas Matthews</a> determines the radio position of the <i><a href="/facts/Third_Cambridge_Catalogue_of_Radio_Sources/T5zYFDIz">3C</a></i> source <a href="/facts/3C_48/DvNq3w5h">3C 48</a> to within 5".</li> <li>1960 – <a href="/facts/Allan_Sandage/Qk1kRoTm">Allan Sandage</a> optically studies <a href="/facts/3C_48/DvNq3w5h">3C 48</a> and observes an unusual blue quasistellar object.</li> <li>1962 – <a href="/facts/Cyril_Hazard/UBB6voCt">Cyril Hazard</a>, M. B. Mackey, and A. J. Shimmins use <a href="/facts/Lunar_occultation/a9Q1KTPe">lunar occultations</a> to determine a precise position for the <a href="/facts/Quasar/HS96328l">quasar</a> <a href="/facts/3C_273/P11TI6Ez">3C 273</a> and deduce that it is a double source.</li> <li>1962 – <a href="/facts/Olin_Eggen/EW77VQCE">Olin Eggen</a>, <a href="/facts/Donald_Lynden-Bell/vLGDqAXr">Donald Lynden-Bell</a>, and <a href="/facts/Allan_Sandage/Qk1kRoTm">Allan Sandage</a> theorize <a href="/facts/Galaxy_formation/uAPtXxr4">galaxy formation</a> by a single (relatively) rapid monolithic collapse, with the halo forming first, followed by the disk.</li> <li>1963 – <a href="/facts/Maarten_Schmidt/WFSwrahI">Maarten Schmidt</a> identifies the redshifted Balmer lines from the quasar <a href="/facts/3C_273/P11TI6Ez">3C 273</a>.</li> <li>1973 – <a href="/facts/Jeremiah_Ostriker/JH74n2JC">Jeremiah Ostriker</a> and <a href="/facts/Jim_Peebles/sJSx27PR">James Peebles</a> discover that the amount of visible matter in the disks of typical spiral galaxies is not enough for Newtonian gravitation to keep the disks from flying apart or drastically changing shape.</li> <li>1973 – Donald Gudehus finds that the diameters of the brightest cluster galaxies have increased due to merging, the diameters of the faintest cluster galaxies have decreased due to tidal distention, and that the Virgo cluster has a substantial peculiar velocity.</li> <li>1974 – <a href="/facts/Bernie_Fanaroff/rEUQxpxL">B. L. Fanaroff</a> and <a href="/facts/Julia_Riley/qDejX3np">J. M. Riley</a> <a href="/facts/Fanaroff-Riley_classification/rjmFVNvD">distinguish</a> between edge-darkened (FR I) and edge-brightened (FR II) radio sources.</li> <li>1976 – <a href="/facts/Sandra_Faber/cDAfcUXk">Sandra Faber</a> and <a href="/facts/Robert_Jackson_(scientist)/Nq53j25z">Robert Jackson</a> discover the Faber-Jackson relation between the <a href="/facts/Luminosity/1tdhpk9l">luminosity</a> of an elliptical galaxy and the <a href="/facts/Velocity/Q3o1LVDe">velocity</a> dispersion in its center. In 1991 the relation is revised by Donald Gudehus.</li> <li>1977 – <a href="/facts/R._Brent_Tully/o4zjLx49">R. Brent Tully</a> and <a href="/facts/J._Richard_Fisher/P0lTVuG7">Richard Fisher</a> publish the <a href="/facts/Tully%25E2%2580%2593Fisher_relation/gP6WRYIc">Tully–Fisher relation</a> between the luminosity of an isolated spiral galaxy and the velocity of the flat part of its <a href="/facts/Rotation_curve/YJyb1Jy3">rotation curve</a>.</li> <li>1978 – Steve Gregory and <a href="/facts/Laird_A._Thompson/3bR2x0FK">Laird Thompson</a> describe the Coma supercluster.</li> <li>1978 – Donald Gudehus finds evidence that clusters of galaxies are moving at several hundred kilometers per second relative to the cosmic microwave background radiation.</li> <li>1978 – <a href="/facts/Vera_Rubin/wKHXHVIp">Vera Rubin</a>, <a href="/facts/Kent_Ford_(astronomer)/HXDx3y4G">Kent Ford</a>, N. Thonnard, and Albert Bosma measure the rotation curves of several spiral galaxies and find significant deviations from what is predicted by the Newtonian gravitation of visible stars.</li> <li>1978 – <a href="/facts/Leonard_Searle/dBgDW2mW">Leonard Searle</a> and Robert Zinn theorize that <a href="/facts/Galaxy_formation/uAPtXxr4">galaxy formation</a> occurs through the merger of smaller groups.</li></ul> <h2 id="late-20th-century">Late 20th century</h2> <ul><li>1981 – <a href="/facts/Robert_Kirshner/2C7K97oM">Robert Kirshner</a>, August Oemler, <a href="/facts/Paul_L._Schechter/oy0PMqDn">Paul Schechter</a>, and Stephen Shectman find evidence for a <a href="/facts/Bo%25C3%25B6tes_Void/6EReq3dl">giant void</a> in <a href="/facts/Bo%25C3%25B6tes/B74JhFQm">Boötes</a>, 250 to 330 million light years across.<a class="footnote-ref" id="fnref:13" href="#fn:13"><sup>13</sup></a></li> <li>1985 – Robert Antonucci and J. Miller discover that the Seyfert II galaxy <a href="/facts/NGC_1068/xHdCsdYT">NGC 1068</a> has broad lines which can only be seen in <a href="/facts/Polarized_light/fP33m0eD">polarized</a> reflected light.<a class="footnote-ref" id="fnref:14" href="#fn:14"><sup>14</sup></a></li> <li>1986 – Amos Yahil, David Walker, and <a href="/facts/Michael_Rowan-Robinson/QE4Ska34">Michael Rowan-Robinson</a> find that the direction of the <a href="/facts/IRAS/MaYMxytq">IRAS</a> galaxy density <a href="/facts/Dipole/G1vRqruD">dipole</a> agrees with the direction of the <a href="/facts/Cosmic_microwave_background/ThB2HkLS">cosmic microwave background</a> temperature dipole.<a class="footnote-ref" id="fnref:15" href="#fn:15"><sup>15</sup></a></li> <li>1987 – David Burstein, <a href="/facts/Roger_Davies_(astrophysicist)/WLNaK3WX">Roger Davies</a>, <a href="/facts/Alan_Dressler/044Vm2kY">Alan Dressler</a>, <a href="/facts/Sandra_Faber/cDAfcUXk">Sandra Faber</a>, <a href="/facts/Donald_Lynden-Bell/vLGDqAXr">Donald Lynden-Bell</a>, R. J. Terlevich, and <a href="/facts/Gary_A._Wegner/ooJQceLX">Gary Wegner</a> claim that a large group of galaxies within about 200 million light years of the Milky Way are moving together towards the "<a href="/facts/Great_Attractor/gFXDuMRg">Great Attractor</a>" in the direction of <a href="/facts/Hydra_(constellation)/71YLVls1">Hydra</a> and <a href="/facts/Centaurus/NQEDC6xA">Centaurus</a>.</li> <li>1987 – <a href="/facts/R._Brent_Tully/o4zjLx49">R. Brent Tully</a> discovers the <a href="/facts/Pisces%25E2%2580%2593Cetus_Supercluster_Complex/x0k4DRJa">Pisces–Cetus Supercluster Complex</a>, a structure one billion light years long and 150 million light years wide.</li> <li>1989 – <a href="/facts/Margaret_Geller/9hd98f7t">Margaret Geller</a> and <a href="/facts/John_Huchra/894DeV5R">John Huchra</a> discover the "<a href="/facts/Great_Wall_(astronomy)/r8XpATsh">Great Wall</a>", a sheet of galaxies more than 500 million light years long and 200 million wide, but only 15 million light years thick.</li> <li>1990 – <a href="/facts/Michael_Rowan-Robinson/QE4Ska34">Michael Rowan-Robinson</a> and Tom Broadhurst discover that the IRAS galaxy IRAS F10214+4724 is the brightest known object in the Universe.</li> <li>1991 – Donald Gudehus discovers a serious systematic bias in certain cluster galaxy data (surface brightness vs. radius parameter, and the D n {\displaystyle D_{n}} method) which affect galaxy distances and evolutionary history; he devises a new distance indicator, the reduced galaxian radius parameter, r g {\displaystyle r_{g}} , which is free of biases.</li> <li>1992 – First detection of large-scale structure in the <a href="/facts/Cosmic_microwave_background/ThB2HkLS">cosmic microwave background</a> indicating the seeds of the first clusters of galaxies in the early Universe.</li> <li>1995 – First detection of small-scale structure in the <a href="/facts/Cosmic_microwave_background/ThB2HkLS">cosmic microwave background</a>.</li> <li>1995 – <a href="/facts/Hubble_Deep_Field/Auz98FQg">Hubble Deep Field</a> survey of galaxies in field 144 arc seconds across.</li> <li>1998 – The <a href="/facts/2dF_Galaxy_Redshift_Survey/zSPHQtLc">2dF Galaxy Redshift Survey</a> maps the large-scale structure in a section of the Universe close to the Milky Way.</li> <li>1998 – The <a href="/facts/Hubble_Deep_Field_South/zwLwtIqY">Hubble Deep Field South</a> is compiled.</li> <li>1998 – Discovery of <a href="/facts/Accelerating_universe/F7X1PAMq">accelerating universe</a>.<a class="footnote-ref" id="fnref:16" href="#fn:16"><sup>16</sup></a></li> <li>2000 – Data from several <a href="/facts/Cosmic_microwave_background/ThB2HkLS">cosmic microwave background</a> experiments give strong evidence that the Universe is "flat" (space is not curved, although space-time is), with important implications for the formation of large-scale structure.</li></ul> <h2 id="early-21st-century">Early 21st century</h2> <ul><li>2001 – First data release from the ongoing <a href="/facts/Sloan_Digital_Sky_Survey/MSHAk1RU">Sloan Digital Sky Survey</a></li> <li>2004 – The <a href="/facts/European_Southern_Observatory/mJtjDbwx">European Southern Observatory</a> discovers <a href="/facts/Abell_1835_IR1916/NPQrTKhD">Abell 1835 IR1916</a>, the most distant galaxy yet seen from Earth.</li> <li>2004 – The <a href="/facts/Arcminute_Microkelvin_Imager/gI7Pubj4">Arcminute Microkelvin Imager</a> begins to map the distribution of distant clusters of galaxies</li> <li>2005 – <a href="/facts/Spitzer_Space_Telescope/Ic1xXIYb">Spitzer Space Telescope</a> data confirm what had been considered likely since the early 1990s from <a href="/facts/Radio_telescope/SxIXUowL">radio telescope</a> data, i.e., that the <a href="/facts/Milky_Way_Galaxy/ulF6lccN">Milky Way Galaxy</a> is a <a href="/facts/Barred_spiral_galaxy/cntSCFX4">barred spiral galaxy</a>.<a class="footnote-ref" id="fnref:17" href="#fn:17"><sup>17</sup></a><a class="footnote-ref" id="fnref:18" href="#fn:18"><sup>18</sup></a></li> <li>2012 – Astronomers report the discovery of the most distant <a href="/facts/Dwarf_galaxy/TKS7W9tA">dwarf galaxy</a> yet found, approximately 10 billion light-years away.<a class="footnote-ref" id="fnref:19" href="#fn:19"><sup>19</sup></a></li> <li>2012 – The <a href="/facts/Huge-LQG/XGTJwRvR">Huge-LQG</a>, a <a href="/facts/Large_quasar_group/ocLbMDlq">large quasar group</a>, one of the largest known structures in the universe, is discovered.<a class="footnote-ref" id="fnref:20" href="#fn:20"><sup>20</sup></a></li> <li>2013 – The galaxy <a href="/facts/Z8_GND_5296/KRGoc80W">Z8 GND 5296</a> is confirmed by <a href="/facts/Spectroscopy/mj71FuNK">spectroscopy</a> to be one of the most distant galaxies found up to this time. Formed just 700 million years after the <a href="/facts/Big_Bang/I5T1vTnv">Big Bang</a>, expansion of the universe has carried it to its current location, about 13 billion light years away from Earth (30 billion light years <a href="/facts/Comoving_distance/55cYbfbY">comoving distance</a>).<a class="footnote-ref" id="fnref:21" href="#fn:21"><sup>21</sup></a></li> <li>2013 – The <a href="/facts/Hercules%25E2%2580%2593Corona_Borealis_Great_Wall/kszfcMlc">Hercules–Corona Borealis Great Wall</a>, a massive <a href="/facts/Galaxy_filament/MFPWn8pS">galaxy filament</a> and the largest known structure in the universe, was discovered through <a href="/facts/Gamma-ray_burst/oRRU6Fhn">gamma-ray burst</a> mapping.<a class="footnote-ref" id="fnref:22" href="#fn:22"><sup>22</sup></a><a class="footnote-ref" id="fnref:23" href="#fn:23"><sup>23</sup></a><a class="footnote-ref" id="fnref:24" href="#fn:24"><sup>24</sup></a></li> <li>2014 – The <a href="/facts/Laniakea_Supercluster/pleQ3nUL">Laniakea Supercluster</a>, the galaxy supercluster that is home to the <a href="/facts/Milky_Way/ulF6lccN">Milky Way</a> is defined via a new way of defining superclusters according to the <a href="/facts/Radial_velocity/B3NmbVLP">relative velocities</a> of <a href="/facts/Galaxy/zCyUvEf7">galaxies</a>.<a class="footnote-ref" id="fnref:25" href="#fn:25"><sup>25</sup></a><a class="footnote-ref" id="fnref:26" href="#fn:26"><sup>26</sup></a> The new definition of the local supercluster subsumes the prior defined local supercluster, the <a href="/facts/Virgo_Supercluster/kUNskKbo">Virgo Supercluster</a>, as an appendage.<a class="footnote-ref" id="fnref:27" href="#fn:27"><sup>27</sup></a><a class="footnote-ref" id="fnref:28" href="#fn:28"><sup>28</sup></a><a class="footnote-ref" id="fnref:29" href="#fn:29"><sup>29</sup></a><a class="footnote-ref" id="fnref:30" href="#fn:30"><sup>30</sup></a><a class="footnote-ref" id="fnref:31" href="#fn:31"><sup>31</sup></a></li> <li>2020 – Astronomers report the discovery of a large cavity in the <a href="/facts/Ophiuchus_Supercluster/EdwDUs3w">Ophiuchus Supercluster</a>, first detected in 2016 and originating from a <a href="/facts/Supermassive_black_hole/BcuTx8Q5">supermassive black hole</a> with the mass of 10 million solar masses. The cavity is a result of <a href="/facts/Ophiuchus_Supercluster_explosion/Hffx9HRT">the largest known explosion in the Universe</a>. The formerly <a href="/facts/Active_galactic_nucleus/qT1owvXz">active galactic nucleus</a> created it by emitting radiation and particle <a href="/facts/Relativistic_jet/QYerB8R3">jets</a>, possibly as a result of a spike in supply of gas to the black hole that could have occurred if a galaxy fell into the centre of the cavity.<a class="footnote-ref" id="fnref:32" href="#fn:32"><sup>32</sup></a><a class="footnote-ref" id="fnref:33" href="#fn:33"><sup>33</sup></a><a class="footnote-ref" id="fnref:34" href="#fn:34"><sup>34</sup></a></li> <li>2020 – Astronomers report to have discovered the <a href="/facts/Disk_galaxy/X1MG3Mg7">disk galaxy</a> <a href="/facts/Wolfe_Disk/PQWkhohw">Wolfe Disk</a>, dating back to when the universe was only 1.5 billion years old, possibly indicating the need to revise theories of <a href="/facts/Galaxy_formation_and_evolution/uAPtXxr4">galaxy formation and evolution</a>.<a class="footnote-ref" id="fnref:35" href="#fn:35"><sup>35</sup></a><a class="footnote-ref" id="fnref:36" href="#fn:36"><sup>36</sup></a><a class="footnote-ref" id="fnref:37" href="#fn:37"><sup>37</sup></a><a class="footnote-ref" id="fnref:38" href="#fn:38"><sup>38</sup></a></li> <li>2020 – The <a href="/facts/South_Pole_Wall/fdezpyIb">South Pole Wall</a> is a massive cosmic structure formed by a giant wall of galaxies (a galaxy filament) that extends across at least 1.37 billion light-years of space, and is located approximately a half billion light-years away.<a class="footnote-ref" id="fnref:39" href="#fn:39"><sup>39</sup></a><a class="footnote-ref" id="fnref:40" href="#fn:40"><sup>40</sup></a><a class="footnote-ref" id="fnref:41" href="#fn:41"><sup>41</sup></a><a class="footnote-ref" id="fnref:42" href="#fn:42"><sup>42</sup></a><a class="footnote-ref" id="fnref:43" href="#fn:43"><sup>43</sup></a><a class="footnote-ref" id="fnref:44" href="#fn:44"><sup>44</sup></a></li> <li>2020 – After a 20-year-long survey, astrophysicists of the <a href="/facts/Sloan_Digital_Sky_Survey/MSHAk1RU">Sloan Digital Sky Survey</a> publish the <a href="/facts/Cosmology/yM19zM7Y">largest, most detailed 3D map of the universe so far</a>, fill a gap of 11 billion years in <a href="/facts/Chronology_of_the_universe/ezBKAdjy">its expansion history</a>, and provide data which supports the theory of a flat <a href="/facts/Shape_of_the_universe/EJFEm9bw">geometry of the universe</a> and confirms that different regions seem to be <a href="/facts/Expansion_of_the_universe/f6Uvt79B">expanding</a> at <a href="/facts/Hubble%2527s_law/FJYfELCP">different speeds</a>.<a class="footnote-ref" id="fnref:45" href="#fn:45"><sup>45</sup></a><a class="footnote-ref" id="fnref:46" href="#fn:46"><sup>46</sup></a></li> <li>2022 – <a href="/facts/James_Webb_Space_Telescope/w4GAWnWX">James Webb Space Telescope</a> (JWST) releases the <a href="/facts/Webb%2527s_First_Deep_Field/cqJADG2o">Webb's First Deep Field</a>.</li> <li>2022 – JWST detects <a href="/facts/CEERS-93316/2sKRdFeD">CEERS-93316</a>, a candidate high-redshift <a href="/facts/Galaxy/zCyUvEf7">galaxy</a>, with an estimated <a href="/facts/Redshift/Qfl4VjDF">redshift</a> of approximately z = 16.7, corresponding to 235.8 million years<a class="footnote-ref" id="fnref:47" href="#fn:47"><sup>47</sup></a> after the <a href="/facts/Big_Bang/I5T1vTnv">Big Bang</a>.<a class="footnote-ref" id="fnref:48" href="#fn:48"><sup>48</sup></a> If confirmed, it is one of the earliest and most distant known galaxies observed.<a class="footnote-ref" id="fnref:49" href="#fn:49"><sup>49</sup></a></li></ul> <h2 id="see-also">See also</h2> <ul><li><a href="/facts/Illustris_project/6QbkyNgt">Illustris project</a></li> <li><a href="/facts/Observable_universe/CdTGMdsp">Large-scale structure of the cosmos</a></li> <li><a href="/facts/Timeline_of_astronomical_maps%2c_catalogs%2c_and_surveys/BmxBzwgS">Timeline of astronomical maps, catalogs, and surveys</a></li> <li><a href="/facts/Timeline_of_cosmological_theories/w64zTeqM">Timeline of cosmological theories</a></li> <li><a href="/facts/UniverseMachine/Vk9Ijg42">UniverseMachine</a></li> <li><a href="/facts/List_of_largest_cosmic_structures/amD8w2ID">List of largest cosmic structures</a></li> <li><a href="/facts/List_of_the_most_distant_astronomical_objects/xutYjJn3">List of the most distant astronomical objects#Timeline of most distant astronomical object recordholders</a></li></ul> <h2 id="references">References</h2> <ol> <li id="fn:1"><p>Josep Puig Montada (September 28, 2007). 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