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Bibliographie Bibliographie Diese Bibliographie listet nur Publikationen, die in der vorliegen- den Monographie auch zitiert oder erwähnt werden. Es wird in der Bibliographie kein Unterschied zwischen Primär- und Sekundärlitera- tur gemacht. Alle Einträge der Publikationen eines Verfassers werden chronologisch nach deren Erscheinungsjahr aufgelistet, gefolgt von Publikationen mit Koautoren, bei mehreren in der Reihenfolge der Nachnamen der Ko-Autoren. Die Namen jedes Autors werden nur beim Ersteintrag vollständig wiedergegeben, danach mit — ersetzt. Diakritische Zeichen werden bei dieser Einsortierung ignoriert, mit der Ausnahme deutscher Umlaute. Bibliographische Abkürzungen AJP: American Journal of Physics, Lancaster, später: College Park AJS: American Journal of Science, New Haven AN: Astronomische Nachrichten, Kiel and Berlin Ann.Chem.Pharm.: Annalen der Chemie und Pharmazie, Heidelberg Ann.chim.: Annales de chimie et de physique, Paris Ann.Phys.: Annalen der Physik, Leipzig Ann.Sci.: Annals of Science, London BJHS: British Journal for the History of Science, London BMFRS: Biographical Memoirs of Fellows of the Royal Society, London BMNAS: Biographical Memoirs of the National Academy of Sciences, Washing- ton © Springer-Verlag GmbH Deutschland 2017 249 K. Hentschel, Lichtquanten, https://doi.org/10.1007/978-3-662-55273-5 250 Bibliographie CRAS: Comptes Rendus hebdomadaires des Séances de l’Académie des Sciences, Paris Hist.Sci.: History of Science, Cambridge HSPS: Historical Studies in the Physical (and Biological) Sciences, später Historical Studies in the Physical and Natural Sciences, Berkeley Nature: Nature, a Weekly Journal of Science, London Natw.: Die Naturwissenschaften. Wochenschrift für die Fortschritte der Naturwissenschaften, der Medizin und der Technik, Berlin Phil.Mag.: Philosophical Magazine, London Phys.Rev.: The Physical Review. A Journal of Experimental and Theoretical Physics, Lancaster Phys.Z.: Physikalische Zeitschrift, Leipzig/Berlin PPSL: Proceedings of the Physical Society, London PRI: Proceedings of the Royal Institution of Great Britain, London PRSL: Proceedings of the Royal Society, London PTRSL: Philosophical Transactions of the Royal Society, London SA: Scientific American, New York SB.W.: Sitzungsberichte der kaiserlich-königlichen Akademie der Wissen- schaften, mathematisch-physikalische Klasse, Wien SHPS: Studies in the History and Philosophy of Science, Cambridge Z.Phys.: Zeitschrift für Physik, Braunschweig and Berlin Achinstein, Peter (2013) Evidence and Method: Scientific Strategies of Isaac Newton and James Clerk Maxwell,Oxford:OUP. Ambroselli, Michael & Chandrasekhar Roychoudhuri (2015) Did Planck, Ein- stein, Bose count indivisible photons, or discrete emission/absorption processes in a black-body cavity?, Proceedings SPIE vol. 9570-9. Andrade, E. N. Da C. (1930/36) The Mechanism of Nature, London: G. Bell & Sons, 1st ed. 1930, 2nd ed. 1936. —(1957) An Approach to Modern Physics, London: G. Bell & Sons, 1957. Anglin, James (2010) Particles of light, Nature 468: 517–618 (s.a. Klaers et al. 2010) Arabatzis, Theodore: Representing Electrons. A Biographical Approach to Theoretical Entities, Chicago: Univ. of Chicago Press, 2006. Arago, François (1853) Mémoire sur la vitesse de la lumière, CRAS 36: 38–49. Armstrong, H. L. (1983) No place for a photon?, American Journal of Physics 51,2: 103–104 (= Komm. zu Berger 1981; s.a. Singh 1984 und Freeman 1984)). Aspect, Alain & Philippe Grangier & Gérard Roger (1982) Experimental rea- lization of Einstein-Poldolsky-Rosen-Bohm Gedankenexperiment.Anew violation of Bell’s inequalities, a) Physical Review Letters 49,2: 91–94; b) Reprint in Meystre & Walls (Hg.) 1991: 382–385. Atlas Cooperation (2017) Evidence for light-by-light scattering in heavy- Ion collisions with the ATLAS detector at the LHC, CERN-EP-2016–316 Bibliographie 251 (Febr. 7, 2017), arXiv:1702.01625v1 [hep-ex], submitted to Nature Physics. Bacciagaluppi, Guido & Antony Valentini (2009) Quantum Theory at the Crossroads – Reconsidering the 1927 Solvay Conference, Cambridge: Cambridge Univ. Press. Badash, Lawrence 1972 The completeness of 19th century science, Isis 63: 48–58. Badino, Massimiliano (2009) The odd couple: Boltzmann, Planck and the application of statistics to physics 1900–1913, Annalen der Physik 18: 81–101. — & Jaume Navarro (Hg.) (2013) Research and Pedagogy: A History of Quantum Physics through its Textbooks, Berlin: Edition Open Access, online unter http://edition-open-access.de/studies/2/index.html Baldzuhn, J. & E. Mohler & W. Martienssen (1989) A wave-particle delayed choice experiment with a single-photon state, Zeitschrift für Physik B77,2: 347–352. Band, W. (1927) Prof. Lewis’ ‚light corpuscles‘, Nature 120: 405–406, = Komm. zu Lewis (1926c). Barkla, Charles Glover (1905) Polarized Röntgen radiation, Philosophical Transactions of the Royal Society of London 204A: 467–479. —(1906) Polarization in secondary Röntgen radiation, ibid. A77: 247–255. —(1907) The nature of x-rays, Nature 76: 761–662, s. a. Bragg (1908a). —(1908a) Homogeneous secondary Röntgen radiation, Philosophical Maga- zine (6) 16: 550–584. —(1908b) Der Stand der Forschung über die sekundäre Röntgenstrahlung, Jahrbuch der Radioaktivität und Elektronik 5: 246–324. —(1910) Erscheinungen beim Durchgange von Röntgenstrahlen, ibid. 7: 1–15. Batchelor, George K. (1996) TheLifeandLegacyofG.I.Taylor, Cambridge: Cambridge University Press. Beaudouin, Charles (2005) Une histoire d’instruments scientifiques,Paris: EDP sciences, 2005. Bechler, Zed (1973) Newton’s search for a mechanistic model of color disper- sion: A suggested interpretation, Archive for History of Exact Sciences 11: 1–37. —(1974) Newton’s law of forces which are inversely as the mass – a sugges- ted interpretation of his later efforts to normalize a mechanistic model of optical dispersion, Centaurus 18: 184–222. Beck, Guido (1927) Zur Theorie des Photoeffekts, Zeitschrift für Physik 41: 443–452. Beller, Mara (1999) Quantum Dialogue The Making of a Revolution Quantum Dialogue, Chicago: Univ. of Chicago Press. 252 Bibliographie Bennet, Abraham (1792) A new suspension of the magnetic needle in- vented for the discovery of minute quantities of magnetic attraction, Philosophical Transactions of the Royal Society London 82: 81–98. C. H. Bennett, W. K. Wootters et al. (1993) Teleporting an unknown quan- tum state via dual classical and Einstein-Podolsky-Rosen channels, Physical Review Letters 70: 1895. Berger, Steven B. (1981) Comment on the localization of the photon, Ameri- can Journal of Physics 49,2: 106, Komm. zu Henderson 1980; s. a. Armstrong 1983. Bergia, Silvio (1987) Who discovered the Bose-Einstein statistics?, in: Manuel G. Doncel (Hg.) Symmetries in Physics, Bellaterra: 223–280. Bertolotti, Mario: The History of the Laser, Bristol: IOP Publishing, 1999. Beth, Richard (1936) Mechanical Detection and Measurement of the Angular Momentum of Light, Physical Review (2) 50: 115–125 u. Bildtafeln. Bjerknes, Vilhelm (1909) Die Kraftfelder, Braunschweig: Vieweg. Bjorken, James D. & Sidney D. Drell (1965/67a) Relativistic Quantum Fields, New York: McGraw Hill, 1965; b) in dt. Übers.: Relativistische Quantenfeldtheorie, Mannheim: BI, 1967. Blair, Thomas (1786) A proposal for ascertaining by experiments whether the velocity of light be affected by the motion of the body from which it is emitted or reflected, and for applying instruments for deciding the question to several optical and astronomical enquiries, Archives of the Royal Society, Mss. L & P. VIII, 182, publ. in Eisenstaedt (2005a). Blum, Alexander (2014) From the necessary to the possible: The genesis of the spin-statistics theorem, European Journal of Physics H 39: 543–574. Blum, A. & Christian Joas (2016) The emergence of emergent entities in quan- tum field theory, Studies in History and Philosophy of Modern Physics, 53: 1–8. Blumenberg, Hans (1957) Licht als Metapher der Wahrheit. Im Vorfeld der philosophischen Begriffsbildung, Studium Generale 10: 432–447. —(1960) Paradigmen zu einer Metapherologie, Archiv für Begriffsgeschichte 6: 68–88. Bodenstein, Max (1942) 100 Jahre Photochemie des Chlorknallgases, Be- richte der deutschen Chemischen Gesellschaft 75: 119. Bohm, David & Basil Hiley (1982) The de Broglie pilot wave theory and the further development and new insights arising out of it, Foundations of Physics 12: 1001–1016. Bohr, Niels (1927/28) The quantum postulate and the recent development of quantum theory, Nature Suppl. 14. April 1928: 580–590 ( Vortrag in Como am 16. Sept. 1927). —(1933) Licht und Leben, Die Naturwissenschaften 21,13: 245–250. —(1949) Discussion with Einstein on epistemological problems in physics, in: Albert Einstein, Philosopher Scientist, hrsg. v. P.A. Schilpp, Evanston, Ill.: Library of Living Philsophers, 1949 (reprint 1951 u. öfter): 199–242. Bibliographie 253 —: Collected Works, Amsterdam: Elsevier, 13 Bde., 1972–2008, Reprint 2008. Bohr, N. & H.A. Kramers & John C. Slater (1924a) The quantum theory of ra- diation, Philosophical Magazine (6) 47: 785–802; b) in dt. Version: Über die Quantentheorie der Strahlung, Zeitschrift für Physik 24: 69–87. Bohr, N. & Ralph de L. Kronig & J.C. Slater: Spinning electrons and the structure of spectra, Nature 117: 264–5, 550, 587. Bordoni, Stefano (2009) Discrete models for electromagnetic radiation: J.J. Thomson and Einstein, in E. Giannetto, G. Giannini & M. Toscano (Hg.) Da Archimede a Majorana: La fisica nel suo divenire, (Atti del XXVI Congresso Nazionale SISFA - Roma 2006), Rimini: Guaraldi 2009: 247–260. —(2011/12) Joseph John
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