Timeline of black hole physics
Template:Short description Template:More references Timeline of black hole physics
Pre-20th centuryEdit
- 1640 — Ismaël Bullialdus suggests an inverse-square gravitational force law
- 1676 — Ole Rømer demonstrates that light has a finite speed<ref>P. 328 of Template:Cite journal</ref>
- 1684 — Isaac Newton writes down his inverse-square law of universal gravitation<ref>Template:Cite book</ref>
- 1758 — Rudjer Josip Boscovich develops his theory of forces, where gravity can be repulsive on small distances. This implied that strange classical bodies that would not allow other bodies to reach their surfaces, such as what we know call white holes, could exist.<ref>Template:Cite book</ref>
- 1784 — John Michell discusses classical bodies which have escape velocities greater than the speed of light<ref>{{#invoke:citation/CS1|citation
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- 1795 — Pierre Laplace discusses classical bodies which have escape velocities greater than the speed of light<ref>Laplace, P.-S. (1799). Allgemeine geographische Ephemeriden herausgegeben von F. von Zach. IV. Band, I. Stück, I. Abhandlung, Weimar; translation in English: Template:Cite book</ref><ref>Colin Montgomery, Wayne Orchiston and Ian Whittingham, "Michell, Laplace and the origin of the Black Hole Concept" Template:Webarchive, Journal of Astronomical History and Heritage, 12(2), 90–96 (2009).</ref>
- 1798 — Henry Cavendish measures the gravitational constant GTemplate:Sfn<ref>'The aim [of experiments like Cavendish's] may be regarded either as the determination of the mass of the Earth,...conveniently expressed...as its "mean density", or as the determination of the "gravitation constant", G'. Cavendish's experiment is generally described today as a measurement of G.' (Clotfelter 1987 p. 210).</ref>
- 1876 — William Kingdon Clifford suggests that the motion of matter may be due to changes in the geometry of space
20th centuryEdit
Before 1960sEdit
- 1909 — Albert Einstein, together with Marcel Grossmann, starts to develop a theory which would bind metric tensor gik, which defines a space geometry, with a source of gravity, that is with mass
- 1910 — Hans Reissner and Gunnar Nordström define Reissner–Nordström singularity, Hermann Weyl solves special case for a point-body source
- 1915 — Albert Einstein presents (David Hilbert presented this independently five days earlier in Göttingen) the complete Einstein field equations at the Prussian Academy meeting in Berlin on 25 November 1915<ref name=Thorne>Template:Cite book</ref>
- 1916 — Karl Schwarzschild solves the Einstein vacuum field equations for uncharged spherically symmetric non-rotating systems<ref>Template:Cite journal</ref>
- 1917 — Paul Ehrenfest gives conditional principle a three-dimensional space
- 1918 — Hans Reissner<ref>Template:Cite journal</ref> and Gunnar Nordström<ref>Template:Cite journal</ref> solve the Einstein–Maxwell field equations for charged spherically symmetric non-rotating systems
- 1918 — Friedrich Kottler gets Schwarzschild solution without Einstein vacuum field equations
- 1923 — George David Birkhoff proves that the Schwarzschild spacetime geometry is the unique spherically symmetric solution of the Einstein vacuum field equations
- 1931 — Subrahmanyan Chandrasekhar calculates, using special relativity, that a non-rotating body of electron-degenerate matter above a certain limiting mass (at 1.4 solar masses) has no stable solutions
- 1939 — Robert Oppenheimer and Hartland Snyder calculate the gravitational collapse of a pressure-free homogeneous fluid sphere into a black hole<ref>Template:Cite journal</ref>
- 1939 - Using the work of Richard Chace Tolman, Robert Oppenheimer and George Volkoff calculate the upper mass limit of a cold, non-rotating neutron star to be approximately 0.7 solar masses.<ref>Template:Cite journal</ref><ref>Template:Cite journal</ref>
- 1958 — David Finkelstein theorises that the Schwarzschild radius is a causality barrier: an event horizon of a black hole<ref>Template:Cite journal</ref>
1960sEdit
- 1963 — Roy Kerr solves the Einstein vacuum field equations for uncharged symmetric rotating systems, deriving the Kerr metric for a rotating black hole<ref>Template:Cite journal</ref><ref >Melia, Fulvio (2009). "Cracking the Einstein code: relativity and the birth of black hole physics, with an Afterword by Roy Kerr", Princeton University Press, Princeton, Template:ISBN</ref>Template:Rp
- 1963 — Maarten Schmidt discovers and analyzes the first quasar, 3C 273, as a highly red-shifted active galactic nucleus, a billion light years away<ref>Template:Cite news</ref>
- 1964 — Yakov Zel’dovich and independently Edwin Salpeter propose that accretion discs around supermassive black holes are responsible for the huge amounts of energy radiated by quasars<ref name="Thorne" />
- 1964 — Hong-Yee Chiu coins the word quasar for a 'quasi-stellar radio source' in his article in Physics Today<ref>Template:Cite journal</ref><ref>{{#invoke:citation/CS1|citation
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- 1964 — The first recorded use of the term "black hole" in writing, by journalist Ann Ewing<ref>Template:Cite book</ref>
- 1965 — Roger Penrose proves that an imploding star will necessarily produce a singularity once it has formed an event horizon<ref name=Penrose1965>Template:Cite journal</ref>
- 1965 — Ezra T. Newman, E. Couch, K. Chinnapared, A. Exton, A. Prakash, and Robert Torrence solve the Einstein–Maxwell field equations for charged, rotating systems
- 1966 — Yakov Zel’dovich and Igor Novikov propose searching for black hole candidates among binary systems in which one star is optically bright and X-ray dark and the other optically dark but X-ray bright (the black hole candidate)<ref name="Thorne" />
- 1967 — Jocelyn Bell discovers and analyzes the first radio pulsar, direct evidence for a neutron star<ref>Template:Cite journal</ref>
- 1967 — Werner Israel presents the proof of the no-hair theorem at King's College London<ref>Template:Cite journal</ref>
- 1967 — John Wheeler introduces the term "black hole" in his lecture to the American Association for the Advancement of Science<ref name="Thorne" />
- 1968 — Brandon Carter uses Hamilton–Jacobi theory to derive first-order equations of motion for a charged particle moving in the external fields of a Kerr–Newman black hole
- 1969 — Roger Penrose discusses the Penrose process for the extraction of the spin energy from a Kerr black hole<ref>Template:Cite journal</ref><ref>Template:Cite bookMisner, Thorne, and Wheeler, Gravitation, Freeman and Company, 1973.</ref><ref>Template:Cite journal</ref>
- 1969 — Roger Penrose proposes the cosmic censorship hypothesis<ref>Template:Cite journal</ref>
After 1960sEdit
- 1972 — Identification of Cygnus X-1/HDE 226868 from dynamic observations as the first binary with a stellar black hole candidate<ref name=aaa305_871>Template:Cite journal</ref>
- 1972 — Stephen Hawking proves that the area of a classical black hole's event horizon cannot decreaseTemplate:SfnTemplate:Sfn
- 1972 — James Bardeen, Brandon Carter, and Stephen Hawking propose four laws of black hole mechanics in analogy with the laws of thermodynamics
- 1972 — Jacob Bekenstein suggests that black holes have an entropy proportional to their surface area due to information loss effects
- 1974 — Stephen Hawking applies quantum field theory to black hole spacetimes and shows that black holes will radiate particles with a black-body spectrum which can cause black hole evaporation<ref>Template:Cite Q</ref><ref>Template:Cite Q</ref>
- 1975 — James Bardeen and Jacobus Petterson show that the swirl of spacetime around a spinning black hole can act as a gyroscope stabilizing the orientation of the accretion disc and jets<ref name="Thorne" />
- 1989 — Identification of microquasar V404 Cygni as a binary black hole candidate system
- 1989 - Eric Poisson and Werner Israel theorize the concept of mass-inflation, a phenomena in which the curvature and gravitational mass parameter inside a spinning or charged black hole grow to infinity as one approaches the inner horizon, causing an infalling observer to experience a singularity at the inner horizon of the black hole.<ref>Template:Cite journal</ref>
- 1994 — Charles Townes and colleagues observe ionized neon gas swirling around the center of our Galaxy at such high velocities that a possible black hole mass at the very center must be approximately equal to that of 3 million suns<ref>Template:Cite journal</ref>
21st centuryEdit
- 2002 — Astronomers at the Max Planck Institute for Extraterrestrial Physics present evidence for the hypothesis that Sagittarius A* is a supermassive black hole at the center of the Milky Way galaxy
- 2002 — Physicists at The Ohio State University publish fuzzball theory, which is a quantum description of black holes positing that they are extended objects composed of strings and don't have singularities.
- 2002 — NASA's Chandra X-ray Observatory identifies double galactic black holes system in merging galaxies NGC 6240
- 2004 — Further observations by a team from UCLA present even stronger evidence supporting Sagittarius A* as a black hole
- 2006 — The Event Horizon Telescope begins capturing data
- 2012 — First visual evidence of black-holes: Suvi Gezari's team in Johns Hopkins University, using the Hawaiian telescope Pan-STARRS 1, publish images of a supermassive black hole 2.7 million light-years away swallowing a red giant<ref>[1] Scientific American – Big Gulp: Flaring Galaxy Marks the Messy Demise of a Star in a Supermassive Black Hole</ref>
- 2015 — LIGO Scientific Collaboration detects the distinctive gravitational waveforms from a binary black hole merging into a final black hole, yielding the basic parameters (e.g., distance, mass, and spin) of the three spinning black holes involved
- 2019 — Event Horizon Telescope collaboration releases the first direct photo of a black hole, the supermassive M87* at the core of the Messier 87 galaxy