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* [[Galileo Galilei]] and [[Simon Stevin]]: heavy and light balls fall together (''contra'' Aristotle).
* [[Galileo Galilei]] and [[Simon Stevin]]: heavy and light balls fall together (''contra'' Aristotle).
* Galileo Galilei and Simon Stevin: [[Hydrostatic paradox]] (Stevin c. 1585, Galileo c. 1610).
* Galileo Galilei and Simon Stevin: [[Hydrostatic paradox]] (Stevin c. 1585, Galileo c. 1610).
* [[Scipione dal Ferro]] (1520) and [[Niccolò Tartaglia]] (1535) independently developed a method for solving [[Cubic equation#Cardano's method|cubic equations]].
* 1520: [[Scipione dal Ferro]] (1520) and [[Niccolò Tartaglia]] (1535) independently developed a method for solving [[Cubic equation#Cardano's method|cubic equations]].
* [[Olbers' paradox]] (the "dark-night-sky paradox") was described by [[Thomas Digges]] in the 16th century, by [[Johannes Kepler]] in the 17th century (1610), by [[Edmond Halley]] and by [[Jean-Philippe de Chéseaux]] in the 18th century, by [[Heinrich Wilhelm Matthias Olbers]] in the 19th century (1823), and definitively by [[William Thomson, 1st Baron Kelvin|Lord Kelvin]] in the 20th century (1901); some aspects of Kelvin's argument had been anticipated in the poet and short-story writer [[Edgar Allan Poe]]'s essay, ''[[Eureka: A Prose Poem]]'' (1848), which also presaged by three-quarters of a century the [[Big Bang]] theory of the [[universe]].<ref name="auto">{{cite journal |last=Cappi |first=Alberto |date=1994 |title=Edgar Allan Poe's Physical Cosmology |journal=Quarterly Journal of the Royal Astronomical Society |volume=35 |pages=177–192 |bibcode=1994QJRAS..35..177C}}</ref><ref>* {{cite journal |last=Rombeck |first=Terry |date=22 January 2005 |title=Poe's little-known science book reprinted |journal=Lawrence Journal-World & News |url= http://www2.ljworld.com/news/2005/jan/22/poes_littleknown_science/}}</ref><ref>[[Marilynne Robinson]], "On Edgar Allan Poe", ''[[The New York Review of Books]]'', vol. LXII, no. 2 (5 February 2015), pp. 4, 6.</ref>
* [[Olbers' paradox]] (the "dark-night-sky paradox") was described by [[Thomas Digges]] in the 16th century, by [[Johannes Kepler]] in the 17th century (1610), by [[Edmond Halley]] and by [[Jean-Philippe de Chéseaux]] in the 18th century, by [[Heinrich Wilhelm Matthias Olbers]] in the 19th century (1823), and definitively by [[William Thomson, 1st Baron Kelvin|Lord Kelvin]] in the 20th century (1901); some aspects of Kelvin's argument had been anticipated in the poet and short-story writer [[Edgar Allan Poe]]'s essay, ''[[Eureka: A Prose Poem]]'' (1848), which also presaged by three-quarters of a century the [[Big Bang]] theory of the [[universe]].<ref name="auto">{{cite journal |last=Cappi |first=Alberto |date=1994 |title=Edgar Allan Poe's Physical Cosmology |journal=Quarterly Journal of the Royal Astronomical Society |volume=35 |pages=177–192 |bibcode=1994QJRAS..35..177C}}</ref><ref>* {{cite journal |last=Rombeck |first=Terry |date=22 January 2005 |title=Poe's little-known science book reprinted |journal=Lawrence Journal-World & News |url= http://www2.ljworld.com/news/2005/jan/22/poes_littleknown_science/}}</ref><ref>[[Marilynne Robinson]], "On Edgar Allan Poe", ''[[The New York Review of Books]]'', vol. LXII, no. 2 (5 February 2015), pp. 4, 6.</ref>
* [[Continental drift]], in varying independent [[iteration]]s, was proposed by [[Abraham Ortelius]] {{Harv|Ortelius|1596}},<ref>{{Citation |last=Romm |first=James |title=A New Forerunner for Continental Drift |journal=Nature |date=3 February 1994 |volume=367 |pages=407–408 |doi=10.1038/367407a0 |postscript=. |issue=6462 |bibcode=1994Natur.367..407R |s2cid=4281585}}</ref> Theodor Christoph Lilienthal (1756),<ref name=schmeling2004>{{Cite web |first=Harro |last=Schmeling |url= http://www.geophysik.uni-frankfurt.de/~schmelin/skripte/Geodynn1-kap1-2-S1-S22-2004.pdf |title=Geodynamik |date=2004 |publisher=University of Frankfurt |language=de}}</ref> [[Alexander von Humboldt]] (1801 and 1845),<ref name=schmeling2004 /> [[Antonio Snider-Pellegrini]] {{Harv|Snider-Pellegrini|1858}}, [[Alfred Russel Wallace]],<ref>{{citation |first=Alfred Russel |last=Wallace |title=Darwinism ... |date=1889 |chapter=12 |publisher=Macmillan |page=341 |chapter-url= https://books.google.com/books?id=0S4aAAAAYAAJ&pg=PA341}}</ref> [[Charles Lyell]],<ref>{{citation |first=Charles |last=Lyell |title=Principles of Geology ... |date=1872 |edition=11th |publisher=John Murray |page=258 |url= https://archive.org/stream/principlesgeolo41lyelgoog#page/n287/mode/1up/}}</ref> Franklin Coxworthy (between 1848 and 1890),<ref>{{cite book |last1=Coxworthy |first1=Franklin |title=Electrical Condition; Or, How and where Our Earth was Created |date=1924 |publisher=J. S. Phillips |url= https://books.google.com/books?id=STj7PAAACAAJ |access-date=6 December 2014}}</ref> [[Roberto Mantovani]] (between 1889 and 1909), [[William Henry Pickering]] (1907),<ref>{{Citation |last=Pickering |first=W. H |title=The Place of Origin of the Moon – The Volcani Problems |journal=Popular Astronomy |volume=15 |pages=274–287 |date=1907 |bibcode=1907PA.....15..274P}},</ref> [[Frank Bursley Taylor]] (1908),<ref>{{cite journal |first=Frank |last=Bursley Taylor |date=3 June 1910 |url= http://babel.hathitrust.org/cgi/pt?id=njp.32101080758822;view=1up;seq=207 |title=Bearing of the Tertiary mountain belt on the origin of the earth’s plan |journal=Bulletin of the Geological Society of America |volume=21 |pages=179–226}}</ref> and [[Alfred Wegener]] (1912).<ref name=weg>{{Citation |last=Wegener |first=Alfred |date=6 January 1912 |title=Die Herausbildung der Grossformen der Erdrinde (Kontinente und Ozeane), auf geophysikalischer Grundlage |journal=Petermanns Geographische Mitteilungen |volume=63 |pages=185–195, 253–256, 305–309 |url= http://epic.awi.de/Publications/Polarforsch2005_1_3.pdf |postscript=. |url-status=dead |archive-url= https://web.archive.org/web/20111004001150/http://epic.awi.de/Publications/Polarforsch2005_1_3.pdf |archive-date=4 October 2011}}</ref> In addition, in 1885 [[Eduard Suess]] had proposed a supercontinent [[Gondwana]]<ref>Eduard Suess, ''Das Antlitz der Erde'' (The Face of the Earth), vol. 1 (Leipzig, (Germany): G. Freytag, 1885), [http://babel.hathitrust.org/cgi/pt?id=mdp.39015048893047;view=1up;seq=792 page 768.] From p. 768: ''"Wir nennen es Gondwána-Land, nach der gemeinsamen alten Gondwána-Flora, … "'' (We name it Gondwána-Land, after the common ancient flora of Gondwána ... )</ref> and in 1893 the [[Tethys Ocean]],<ref>{{cite journal |first=Edward |last=Suess |date=March 1893 |url= https://books.google.com/books?id=yQUVAAAAYAAJ&pg=PA180 |via=Google Books |title=Are ocean depths permanent? |journal=Natural Science: A Monthly Review of Scientific Progress |volume=2 |pages=180–187 |quote=This ocean we designate by the name 'Tethys', after the sister and consort of Oceanus. The latest successor of the Tethyan Sea is the present Mediterranean.}}</ref> assuming a [[Land bridge#Land bridge theory|land-bridge]] between the present continents submerged in the form of a [[geosyncline]]; and in 1895 [[John Perry (engineer)|John Perry]] had written a paper proposing that the earth's interior was fluid, and disagreeing with [[Lord Kelvin]] on the age of the earth.<ref>{{cite journal |last=Perry |first=John |date=1895 |title=On the age of the earth |journal=[[Nature (journal)|Nature]] |volume=51 |url= http://babel.hathitrust.org/cgi/pt?id=mdp.39015038750868;view=1up;seq=266 |via=Hathi Trust |pages=224–227, 341–342, 582–585}}</ref>
* 1596: [[Continental drift]], in varying independent [[iteration]]s, was proposed by [[Abraham Ortelius]] {{Harv|Ortelius|1596}},<ref>{{Citation |last=Romm |first=James |title=A New Forerunner for Continental Drift |journal=Nature |date=3 February 1994 |volume=367 |pages=407–408 |doi=10.1038/367407a0 |postscript=. |issue=6462 |bibcode=1994Natur.367..407R |s2cid=4281585}}</ref> Theodor Christoph Lilienthal (1756),<ref name=schmeling2004>{{Cite web |first=Harro |last=Schmeling |url= http://www.geophysik.uni-frankfurt.de/~schmelin/skripte/Geodynn1-kap1-2-S1-S22-2004.pdf |title=Geodynamik |date=2004 |publisher=University of Frankfurt |language=de}}</ref> [[Alexander von Humboldt]] (1801 and 1845),<ref name=schmeling2004 /> [[Antonio Snider-Pellegrini]] {{Harv|Snider-Pellegrini|1858}}, [[Alfred Russel Wallace]],<ref>{{citation |first=Alfred Russel |last=Wallace |title=Darwinism ... |date=1889 |chapter=12 |publisher=Macmillan |page=341 |chapter-url= https://books.google.com/books?id=0S4aAAAAYAAJ&pg=PA341}}</ref> [[Charles Lyell]],<ref>{{citation |first=Charles |last=Lyell |title=Principles of Geology ... |date=1872 |edition=11th |publisher=John Murray |page=258 |url= https://archive.org/stream/principlesgeolo41lyelgoog#page/n287/mode/1up/}}</ref> Franklin Coxworthy (between 1848 and 1890),<ref>{{cite book |last1=Coxworthy |first1=Franklin |title=Electrical Condition; Or, How and where Our Earth was Created |date=1924 |publisher=J. S. Phillips |url= https://books.google.com/books?id=STj7PAAACAAJ |access-date=6 December 2014}}</ref> [[Roberto Mantovani]] (between 1889 and 1909), [[William Henry Pickering]] (1907),<ref>{{Citation |last=Pickering |first=W. H |title=The Place of Origin of the Moon – The Volcani Problems |journal=Popular Astronomy |volume=15 |pages=274–287 |date=1907 |bibcode=1907PA.....15..274P}},</ref> [[Frank Bursley Taylor]] (1908),<ref>{{cite journal |first=Frank |last=Bursley Taylor |date=3 June 1910 |url= http://babel.hathitrust.org/cgi/pt?id=njp.32101080758822;view=1up;seq=207 |title=Bearing of the Tertiary mountain belt on the origin of the earth’s plan |journal=Bulletin of the Geological Society of America |volume=21 |pages=179–226}}</ref> and [[Alfred Wegener]] (1912).<ref name=weg>{{Citation |last=Wegener |first=Alfred |date=6 January 1912 |title=Die Herausbildung der Grossformen der Erdrinde (Kontinente und Ozeane), auf geophysikalischer Grundlage |journal=Petermanns Geographische Mitteilungen |volume=63 |pages=185–195, 253–256, 305–309 |url= http://epic.awi.de/Publications/Polarforsch2005_1_3.pdf |postscript=. |url-status=dead |archive-url= https://web.archive.org/web/20111004001150/http://epic.awi.de/Publications/Polarforsch2005_1_3.pdf |archive-date=4 October 2011}}</ref> In addition, in 1885 [[Eduard Suess]] had proposed a supercontinent [[Gondwana]]<ref>Eduard Suess, ''Das Antlitz der Erde'' (The Face of the Earth), vol. 1 (Leipzig, (Germany): G. Freytag, 1885), [http://babel.hathitrust.org/cgi/pt?id=mdp.39015048893047;view=1up;seq=792 page 768.] From p. 768: ''"Wir nennen es Gondwána-Land, nach der gemeinsamen alten Gondwána-Flora, … "'' (We name it Gondwána-Land, after the common ancient flora of Gondwána ... )</ref> and in 1893 the [[Tethys Ocean]],<ref>{{cite journal |first=Edward |last=Suess |date=March 1893 |url= https://books.google.com/books?id=yQUVAAAAYAAJ&pg=PA180 |via=Google Books |title=Are ocean depths permanent? |journal=Natural Science: A Monthly Review of Scientific Progress |volume=2 |pages=180–187 |quote=This ocean we designate by the name 'Tethys', after the sister and consort of Oceanus. The latest successor of the Tethyan Sea is the present Mediterranean.}}</ref> assuming a [[Land bridge#Land bridge theory|land-bridge]] between the present continents submerged in the form of a [[geosyncline]]; and in 1895 [[John Perry (engineer)|John Perry]] had written a paper proposing that the earth's interior was fluid, and disagreeing with [[Lord Kelvin]] on the age of the earth.<ref>{{cite journal |last=Perry |first=John |date=1895 |title=On the age of the earth |journal=[[Nature (journal)|Nature]] |volume=51 |url= http://babel.hathitrust.org/cgi/pt?id=mdp.39015038750868;view=1up;seq=266 |via=Hathi Trust |pages=224–227, 341–342, 582–585}}</ref>


== 17th century ==
== 17th century ==

Revision as of 02:09, 6 January 2024

Historians and sociologists have remarked the occurrence, in science, of "multiple independent discovery". Robert K. Merton defined such "multiples" as instances in which similar discoveries are made by scientists working independently of each other.[1] "Sometimes", writes Merton, "the discoveries are simultaneous or almost so; sometimes a scientist will make a new discovery which, unknown to him, somebody else has made years before."[2]

Commonly cited examples of multiple independent discovery are the 17th-century independent formulation of calculus by Isaac Newton, Gottfried Wilhelm Leibniz and others, described by A. Rupert Hall;[3] the 18th-century discovery of oxygen by Carl Wilhelm Scheele, Joseph Priestley, Antoine Lavoisier and others; and the theory of the evolution of species, independently advanced in the 19th century by Charles Darwin and Alfred Russel Wallace.

Multiple independent discovery, however, is not limited to such famous historic instances. Merton believed that it is multiple discoveries, rather than unique ones, that represent the common pattern in science.[4]

Merton contrasted a "multiple" with a "singleton"—a discovery that has been made uniquely by a single scientist or group of scientists working together.[5]

A distinction is drawn between a discovery and an invention, as discussed for example by Bolesław Prus.[6] However, discoveries and inventions are inextricably related, in that discoveries lead to inventions, and inventions facilitate discoveries; and since the same phenomenon of multiplicity occurs in relation to both discoveries and inventions, this article lists both multiple discoveries and multiple inventions.

3rd century BCE

Aristarchos

13th century CE

14th century

Copernicus

16th century

Galileo
Ortelius

17th century

Newton
Leibniz

18th century

Scheele
Laplace

19th century

Gauss
Faraday
Darwin
Mendeleyev
Bell
Ramón y Cajal
Cybulski
Becquerel

20th century

Nettie Stevens
Smoluchowski
Tykociński-Tykociner
Einstein
Alexander Friedmann
Hsien Wu
Szilárd
Koprowski
Purcell
Nambu
Higgs
Schwinger
Vine
Penzias
Schally
Baltimore
Alvarez
Barré-Sinoussi
Immerman
Cocks
Wilczek
Ting
Cech
Perlmutter, Riess, Schmidt

21st century

McDonald, Kajita
Allison
Šikšnys
Patapoutian

Quotations

"When the time is ripe for certain things, these things appear in different places in the manner of violets coming to light in early spring."

— Farkas Bolyai to his son János Bolyai, urging him to claim the invention of non-Euclidean geometry without delay,
quoted in Ming Li and Paul Vitanyi, An introduction to Kolmogorov Complexity and Its Applications, 1st ed., 1993, p. 83.

"[Y]ou do not [make a discovery] until a background knowledge is built up to a place where it's almost impossible not to see the new thing, and it often happens that the new step is done contemporaneously in two different places in the world, independently."

— a physicist Nobel laureate interviewed by Harriet Zuckerman, in Scientific Elite: Nobel Laureates in the United States, 1977, p. 204.

"[A] man can no more be completely original ... than a tree can grow out of air."

— George Bernard Shaw, preface to Major Barbara (1905).

I never had an idea in my life. My so-called inventions already existed in the environment – I took them out. I've created nothing. Nobody does. There's no such thing as an idea being brain-born; everything comes from the outside.

See also

Notes

  1. ^ Priyamvada Natarajan notes that, while Le Verrier and Adams "shared credit for the discovery [of Neptune] until fairly recently ... historians of science [have] revealed that while Adams did perform some interesting calculations, his were not as precise or as accurate as Le Verrier's, and, moreover, he had not published his work, while Le Verrier had shared his predictions." Le Verrier "presented the calculated position of th[e] unseen planet [Neptune] to the French Academy of Sciences in Paris on August 31, 1846, barely two days before Adams mailed his own solution to the astronomer royal, George Airy, at the Greenwich Observatory so that his calculations could be checked. Neither Adams nor Le Verrier knew that the other had been researching Uranus's orbit." Natarajan also notes that, "Though Neptune wasn't properly identified until 1846, it had been observed much earlier.": by Galileo Galilei (1612, 1613); by Michel Lalande (8 and 10 May 1795), nephew and pupil of French astronomer Joseph-Jérôme Lalande; by Scottish astronomer John Lambert, while working at the Munich Observatory in 1845 and 1846; and by James Challis (4 and 12 August 1846).[37]

References

  1. ^ Merton, Robert K. (December 1963). "Resistance to the Systematic Study of Multiple Discoveries in Science". European Journal of Sociology. 4 (2): 237–282. doi:10.1017/S0003975600000801. JSTOR 23998345. S2CID 145650007. Reprinted in: Merton, Robert K. (15 September 1996). On Social Structure and Science. University of Chicago Press. pp. 305–. ISBN 978-0-226-52070-4.
  2. ^ Merton, Robert K. (1973). The Sociology of Science: Theoretical and Empirical Investigations. University of Chicago Press. p. 371. ISBN 978-0-226-52092-6.
  3. ^ A. Rupert Hall, Philosophers at War, New York, Cambridge University Press, 1980.
  4. ^ Robert K. Merton, "Singletons and Multiples in Scientific Discovery: a Chapter in the Sociology of Science", Proceedings of the American Philosophical Society, 105: 470–86, 1961. Reprinted in Robert K. Merton, The Sociology of Science: Theoretical and Empirical Investigations, Chicago, University of Chicago Press, 1973, pp. 343–70.
  5. ^ Robert K. Merton, On Social Structure and Science, p. 307.
  6. ^ Bolesław Prus, O odkryciach i wynalazkach (On Discoveries and Inventions): A Public Lecture Delivered on 23 March 1873 by Aleksander Głowacki [Bolesław Prus], Passed by the [Russian] Censor (Warsaw, 21 April 1873), Warsaw, Printed by F. Krokoszyńska, 1873, p. 12.
  7. ^ Owen Gingerich, "Did Copernicus Owe a Debt to Aristarchus?" Journal for the History of Astronomy, vol. 16, no. 1 (February 1985), pp. 37–42. [1]
  8. ^ Dava Sobel, A More Perfect Heaven: How Copernicus Revolutionized the Cosmos, New York, Walker & Company, 2011, ISBN 978-0-8027-1793-1, pp. 18–19, 179–82.
  9. ^ "Copernicus seems to have drawn up some notes [on the displacement of good coin from circulation by debased coin] while he was at Olsztyn in 1519. He made them the basis of a report on the matter, written in German, which he presented to the Prussian Diet held in 1522 at Grudziądz .... He later drew up a revised and enlarged version of his little treatise, this time in Latin, and setting forth a general theory of money, for presentation to the Diet of 1528." Angus Armitage, The World of Copernicus, 1951, p. 91.
  10. ^ Αριστοφάνης. "Βάτραχοι". Βικιθήκη. Retrieved 19 April 2013.
  11. ^ a b Cappi, Alberto (1994). "Edgar Allan Poe's Physical Cosmology". Quarterly Journal of the Royal Astronomical Society. 35: 177–192. Bibcode:1994QJRAS..35..177C.
  12. ^ * Rombeck, Terry (22 January 2005). "Poe's little-known science book reprinted". Lawrence Journal-World & News.
  13. ^ Marilynne Robinson, "On Edgar Allan Poe", The New York Review of Books, vol. LXII, no. 2 (5 February 2015), pp. 4, 6.
  14. ^ Romm, James (3 February 1994), "A New Forerunner for Continental Drift", Nature, 367 (6462): 407–408, Bibcode:1994Natur.367..407R, doi:10.1038/367407a0, S2CID 4281585.
  15. ^ a b Schmeling, Harro (2004). "Geodynamik" (PDF) (in German). University of Frankfurt.
  16. ^ Wallace, Alfred Russel (1889), "12", Darwinism ..., Macmillan, p. 341
  17. ^ Lyell, Charles (1872), Principles of Geology ... (11th ed.), John Murray, p. 258
  18. ^ Coxworthy, Franklin (1924). Electrical Condition; Or, How and where Our Earth was Created. J. S. Phillips. Retrieved 6 December 2014.
  19. ^ Pickering, W. H (1907), "The Place of Origin of the Moon – The Volcani Problems", Popular Astronomy, 15: 274–287, Bibcode:1907PA.....15..274P,
  20. ^ Bursley Taylor, Frank (3 June 1910). "Bearing of the Tertiary mountain belt on the origin of the earth's plan". Bulletin of the Geological Society of America. 21: 179–226.
  21. ^ Wegener, Alfred (6 January 1912), "Die Herausbildung der Grossformen der Erdrinde (Kontinente und Ozeane), auf geophysikalischer Grundlage" (PDF), Petermanns Geographische Mitteilungen, 63: 185–195, 253–256, 305–309, archived from the original (PDF) on 4 October 2011.
  22. ^ Eduard Suess, Das Antlitz der Erde (The Face of the Earth), vol. 1 (Leipzig, (Germany): G. Freytag, 1885), page 768. From p. 768: "Wir nennen es Gondwána-Land, nach der gemeinsamen alten Gondwána-Flora, … " (We name it Gondwána-Land, after the common ancient flora of Gondwána ... )
  23. ^ Suess, Edward (March 1893). "Are ocean depths permanent?". Natural Science: A Monthly Review of Scientific Progress. 2: 180–187 – via Google Books. This ocean we designate by the name 'Tethys', after the sister and consort of Oceanus. The latest successor of the Tethyan Sea is the present Mediterranean.
  24. ^ Perry, John (1895). "On the age of the earth". Nature. 51: 224–227, 341–342, 582–585 – via Hathi Trust.
  25. ^ Roger Penrose, The Road to Reality, Vintage Books, 2005, p. 103.
  26. ^ Thomas S. Kuhn, The Structure of Scientific Revolutions, Chicago, The University of Chicago Press, 1996, p. 17.
  27. ^ Vladimir D. Shiltsev, "Nov. 19, 1771: Birth of Mikhail Lomonosov, Russia's first modern scientist", APS [American Physical Society] News, November 2011 (vol. 20, no. 10) [2].
  28. ^ Anirudh, "10 Major Contributions of Antoine Lavoisier", 17 October 2017 [3].
  29. ^ "MICHAEL SENDIVOGIUS, ROSICRUCIAN, and FATHER OF STUDIES OF OXYGEN" (PDF).
  30. ^ Alan Ellis, "Black Holes – Part 1 – History", Astronomical Society of Edinburgh, Journal 39, 1999 Archived 6 October 2017 at the Wayback Machine. A description of Michell's theory of black holes.
  31. ^ a b Stephen Hawking, A Brief History of Time, Bantam, 1996, pp. 43–45.
  32. ^ "Hong's essential insight is the same as Malthus's". Wm Theodore de Bary, Sources of East Asian Tradition, vol. 2: The Modern Period, New York, Columbia University Press, 2008, p. 85.
  33. ^ Gauss, Carl Friedrich, "Nachlass: Theoria interpolationis methodo nova tractata", Werke, Band 3, Göttingen, Königliche Gesellschaft der Wissenschaften, 1866, pp. 265–327.
  34. ^ Heideman, M. T., D. H. Johnson, and C. S. Burrus, "Gauss and the history of the fast Fourier transform", Archive for History of Exact Sciences, vol. 34, no. 3 (1985), pp. 265–277.
  35. ^ Roger Penrose, The Road to Reality, Vintage Books, 2005, p. 81.
  36. ^ Halliday et al., Physics, vol. 2, 2002, p. 775.
  37. ^ a b Priyamvada Natarajan, "In Search of Planet X" (review of Dale P. Cruikshank and William Sheehan, Discovering Pluto: Exploration at the Edge of the Solar System, University of Arizona Press, 475 pp.; Alan Stern and David Grinspoon, Chasing New Horizons: Inside the Epic First Mission to Pluto, Picador, 295 pp.; and Adam Morton, Should We Colonize Other Planets?, Polity, 122 pp.), The New York Review of Books, vol. LXVI, no. 16 (24 October 2019), pp. 39–41. (p. 39.)
  38. ^ "Aug. 18, 1868: Helium Discovered During Total Solar Eclipse", https://www.wired.com/thisdayintech/2009/08/dayintech_0818/
  39. ^ Bolesław Prus, On Discoveries and Inventions: A Public Lecture Delivered on 23 March 1873 by Aleksander Głowacki [Bolesław Prus], Passed by the [Russian] Censor (Warsaw, 21 April 1873), Warsaw, Printed by F. Krokoszyńska, 1873, [4], p. 13.
  40. ^ Christopher Kasparek, review of Robert Olby, The Path to the Double Helix, in Zagadnienia naukoznawstwa [Logology, or Science of Science], Warsaw, Polish Academy of Sciences, vol. 14, no. 3 (1978), pp. 461–63.
  41. ^ Wilkinson, Alec, "Illuminating the Brain's 'Utter Darkness'" (review of Benjamin Ehrlich, The Brain in Search of Itself: Santiago Ramón y Cajal and the Story of the Neuron, Farrar, Straus and Giroux, 2023, 447 pp.; and Timothy J. Jorgensen, Spark: The Life of Electricity and the Electricity of Life, Princeton University Press, 2021, 436 pp.), The New York Review of Books, vol. LXX, no. 2 (9 February 2023), pp. 32, 34–35. (information cited, on pp. 32 and 34.)
  42. ^ Maury Klein, Chapter 9: "The Cowbird, The Plugger, and the Dreamer", The Power Makers: Steam, Electricity, and the Men Who Invented Modern America, Bloomsbury Publishing USA, 2010.
  43. ^ Kenneth E. Hendrickson III, The Encyclopedia of the Industrial Revolution in World History, volume 3, Rowman & Littlefield, 2014, p. 564.
  44. ^ Isaac Asimov, Asimov's Biographical Encyclopedia of Science and Technology, p. 933.
  45. ^ N.E. Collinge, The Laws of Indo-European, pp. 149–52.
  46. ^ Collinge, N. E. (1 January 1985). The Laws of Indo-European. John Benjamins Publishing. ISBN 978-9027235305.
  47. ^ Skalski, J. H.; Kuch, J. (April 2006). "Polish thread in the history of circulatory physiology". Journal of Physiology and Pharmacology. 57 (Suppl 1): 5–41. PMID 16766800.
  48. ^ Yamashima, T. (May 2003). "Jokichi Takamine (1854–1922), the samurai chemist, and his work on adrenalin". Journal of Medical Biography. 11 (2): 95–102. doi:10.1177/096777200301100211. PMID 12717538. S2CID 32540165.
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