Heirs of the revolution: X-ray diffraction and the birth of the Mineralogical Society of America

Peter J. Heaney

doi:10.2138/am-2020-7205

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Heirs of the revolution: X-ray diffraction and the birth of the Mineralogical Society of America

Peter J. Heaney

Veröffentlicht/Copyright: 30. Dezember 2019

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Aus der Zeitschrift American Mineralogist Band 105 Heft 1

Abstract

The founding of the Mineralogical Society of America (MSA) in 1919 followed so closely on the heels of the discovery of X‑ray diffraction (XRD) in 1912 that one might hypothesize a causal link. Was MSA born out of this scientific revolution? The formation of our Society conventionally is attributed to the desire for a professional journal and the need to emerge from the shadow of the Geological Society of America, but these issues were not new in 1919. This review argues that MSA’s birth can be understood by an exploration of two historical strains: (1) Although modern notions of atomism traditionally are associated with the emergence of the kinetic theory of gases in the late 19th century, mineralogists had invoked ordered atomic spheres as the fundamental metaphor for crystalline structures over a century earlier, leading directly to W.L. Bragg’s discovery of the atomic design in halite; and (2) in contrast to the broader chemistry community, mineralogists were uniquely poised to embrace X‑ray diffraction and the revolution in crystallography that attended it. This revelation gave rise to a sense of distinct identity.

An examination of MSA’s early records unambiguously reveals that U. S. mineralogists were closely attuned to the crystallographic insurgency as it took place across the Atlantic. In particular, Edgar T. Wherry, one of the organizers of the American Mineralogist and of the Society, actively disseminated information about the new discoveries to his colleagues in the United States. Other founders of MSA similarly championed the transformative character of the new crystallography, thereby warranting the establishment of a specialized professional society. The continuing force of the revolution is revealed in a counter-reaction a century later, as mineralogists have renewed their focus on phases at the boundary between crystals and glasses, leading to reconsiderations of the meaning of crystallinity.

Keywords: Mineralogical Society of America; mineralogy; crystallography; X-ray diffraction; history of science; Invited Centennial article; Review

Acknowledgments and Funding

Dedicated to J. Alexander Speer on his retirement as Executive Director of MSA in thanks for his many years of selfless service. Early drafts of this paper were greatly improved by stimulating discussions with and helpful comments by Charlie Burnham and Jeffrey Post. I also thank journal reviewers Charles Geiger and Keith Putirka, whose criticisms tightened the focus of the manuscript, and associate editor Warren Huff for handling this unusually long contribution. The author acknowledges support from National Science Foundation Grant EAR1552211.

References cited

Allen, E.T. (1916) The composition of natural bornite. American Journal of Sci- ence, 245, 409–413.10.2475/ajs.s4-41.245.409Suche in Google Scholar

Armstrong, H.E. (1927) Poor common salt! Nature, 120, 478.10.1038/120478b0Suche in Google Scholar

Assmus, A. (1995) Early history of X-rays. Beam Line, 25, 10–24.Suche in Google Scholar

Aulthier, A. (2004) Dynamical theory of X-ray diffraction. Oxford University Press.10.1093/acprof:oso/9780198528920.001.0001Suche in Google Scholar

Aulthier, A. (2013) Early Days of X-ray Crystallography. Oxford University Press.10.1093/acprof:oso/9780199659845.001.0001Suche in Google Scholar

Barlow, W. (1883) Probable nature of the internal symmetry of crystals. Nature, 29, 186–188 and 205–207.10.1038/029186a0Suche in Google Scholar

Barlow, W. (1894) Über die Geometrischen Eigenschaften homogener starrer Strukturen und ihre Anwendung auf Krystalle. Zeitschrift für Krystallographie und Minerologie, 23, 1–63.Suche in Google Scholar

Barlow, W. (1898) XXVI. Geometrische Untersuchung über eine mechanische Ursache der Homogenität der Structur und der Symmetrie; mit besonderer Anwendung auf Krystallisation und chemische Verbindung. Zeitschrift für Kristallographie-Crystalline Materials, 29, 433–588.10.1524/zkri.1898.29.1.433Suche in Google Scholar

Barlow, W., and Pope, W.J. (1906) A development of the atomic theory which correlates chemical and crystalline structure and leads to a demonstration of the nature of valency. Journal of the Chemical Society, Transactions, 89, 1675–1744.10.1039/CT9068901675Suche in Google Scholar

Barlow, W., and Pope, W.J. (1907) The relation between the crystalline form and the chemical con- stitution of simple inorganic substances. Journal of the Chemical Society, Transactions, 91, 1150–1177.10.1039/CT9079101150Suche in Google Scholar

Barton, I. (2019) Trends in the discovery of new minerals over the last century. American Mineralogist, 104, 641–651.10.2138/am-2019-6844Suche in Google Scholar

Bates, A.C. (1916) Arthur Chamberlain and his magazines. American Mineralogist, 1, 1–2.Suche in Google Scholar

Bayley, W.S. (1910) Elementary Crystallography. McGraw-Hill.Suche in Google Scholar

Berzelius, J. J. (1814) Attempt to Establish a Pure Scientific System of Mineralogy by the Application of the Electro-Chemical Theory and the Chemical Proportions. Translated by John Black. C. Baldwin.Suche in Google Scholar

Berzelius, J. J. (1824) Om de förändringar i det chemiska Mineralsystemet, som blifva en nödvändig följd af isomorpha kroppars egenskap att ersätta hvarandra i obestämda förhållanden. Konglig Vetenskaps-Academiens Handlingar, p. 112–142.Suche in Google Scholar

Blackmore, J.T. (1972) Ernst Mach: His Work, Life, and Influence. University of California Press, Berkeley.10.1525/9780520325708Suche in Google Scholar

Böhr, N. (1913) I. On the constitution of atoms and molecules. The London, Edin- burgh, and Dublin Philosophical Magazine and Journal of Science, 26, 1–25.10.1080/14786441308634955Suche in Google Scholar

Boscovich, R.G. (1758) Philosophiae naturalis theoria redacta ad unicam legem virium in natura existentium. Prostat Viennae Austriae, Officina Libraria Kaliwodiana.Suche in Google Scholar

Bragg, W.H. (1912) X-rays and crystals. Nature, 90, 219.10.1038/090219a0Suche in Google Scholar

Bragg, W.H., and Bragg, W.L. (1913) The structure of the diamond. Proceedings of the Royal Society of London. Series A, 89, 277–291.Suche in Google Scholar

Bragg, W.H. and Bragg, W.L. (1915) X-rays and Crystal Structure. G. Bell and Sons, London.10.1259/arr.1915.0160Suche in Google Scholar

Bragg, W.L. (1912) The specular reflection of X-rays. Nature, 90, 410.10.1038/090410b0Suche in Google Scholar

Bragg, W.L. (1913a) The diffraction of short electromagnetic waves by a crystal. Pro- ceedings of the Cambridge Philosophical Society, 17, 43–57.Suche in Google Scholar

Bragg, W.L. (1913b) The structure of some crystals as indicated by their diffraction of X-rays. Proceedings of the Royal Society of London Series A, 89, 248–277.10.1098/rspa.1913.0083Suche in Google Scholar

Bragg, W.L. (1914) The analysis of crystals by the X-ray spectrometer. Proceedings of the Royal Society of London Series A, 90, 468–489.Suche in Google Scholar

Bragg, W.L. (1949) Acceptance of the Roebling Medal of the Mineralogical Society of America. American Mineralogist, 34, 238–241.Suche in Google Scholar

Bragg, W.L. (1962) Personal reminiscences. In P.P. Ewald, Ed., Fifty Years of X-ray Diffraction, pp. 531–539. International Union of Crystallography, Glasgow.10.1007/978-1-4615-9961-6_44Suche in Google Scholar

Bravais, A. (1851) Etudes cristallographiques. Journal de l’Ecole Polytechnique, 20, 101–276.Suche in Google Scholar

Brock, W.H., and Knight, D.M. (1965) The atomic debates: “Memorable and interesting evenings in the life of the Chemical Society.” Isis, 56, 5–25.10.1086/349922Suche in Google Scholar

Brown, C.M. (2014). Benjamin Silliman: A life in the young republic. Princeton University Press.Suche in Google Scholar

Brown, W.L., and Parsons, I. (1984) The nature of potassium feldspar, exsolution microtextures and development of dislocations as a function of composition in perthitic alkali feldspars. Contributions to Mineralogy and Petrology, 86, 335–341.10.1007/BF01187138Suche in Google Scholar

Bruce, A. (1968) The American Mineralogical Journal. Contributions to the History of Geology, vol. 1. Hafner Publishing, New York.Suche in Google Scholar

Brush, S.G. (1968) Mach and atomism. Synthese, 18, 192–215.10.1007/BF00413775Suche in Google Scholar

Buddington, A.F. (1937) Memorial of Alexander Hamilton Phillips. American Mineralogist, 22, 1094–1098.Suche in Google Scholar

Buerger, M.J. (1990) Brief history of structure determination. In Lima-de-Faria, Ed., Historical Atlas of Crystallography, pp. 109–123. Kluwer.Suche in Google Scholar

Burdick, C.L. (1958) The genesis and beginnings of X-ray crystallography at Caltech. Physics Today, 11, 20.10.1007/978-1-4615-9961-6_47Suche in Google Scholar

Burdick, C.L., and Ellis, J.H. (1917a) The crystal structure of chalcopyrite deter- mined by X-rays. Journal of the American Chemical Society, 39, 2518–2525.10.1021/ja02257a002Suche in Google Scholar

Burdick, C.L., and Ellis, J.H. (1917b) The crystal structure of chalcopyrite determined by X-rays. Pro- ceedings of the National Academy of Sciences, 3, 644–649.10.1073/pnas.3.11.644Suche in Google Scholar PubMed PubMed Central

Caraballo, M.A., Michel, F.M., and Hochella, M.F. Jr. (2015) The rapid expansion of environmental mineralogy in unconventional ways: Beyond the accepted definition of a mineral, the latest technology, and using nature as our guide. American Mineralogist, 100, 14–25.10.2138/am-2015-4749Suche in Google Scholar

Chalmers, A. (2014) Atomism from the 17th to the 20th Century. In E.N. Zalta, Ed., The Stanford Encyclopedia of Philosophy URL https://plato.stanford.edu/archives/win2014/entries/atomism-modern/Suche in Google Scholar

Christidis, G.E., and Huff, W.D. (2009) Geological aspects and genesis of bentonites. Elements, 5, 93–98.10.2113/gselements.5.2.93Suche in Google Scholar

Cölfen, H., and Antonietti, M. (2005) Mesocrystals: inorganic superstructures made by highly parallel crystallization and controlled alignment. Angewandte Chemie International Edition, 44, 5576–5591.10.1002/anie.200500496Suche in Google Scholar PubMed

Dalton, J. (1808) A New System of Chemical Philosophy. S. Russell, Manchester.10.5479/sil.324338.39088000885681Suche in Google Scholar

Dana, E. S. (1912) A Textbook of Mineralogy. Wiley.Suche in Google Scholar

Dana, J.D. (1837) A System of Mineralogy. Durrie & Peck and Herrick & Noyes, New Haven.Suche in Google Scholar

Dana, J.D. (1845) Observations on pseudomorphism. American Journal of Science and Arts, 48, 81–92.Suche in Google Scholar

Dana, J.D. (1854) A System of Mineralogy, 4th ed. Putnman.Suche in Google Scholar

Dana, J.D., and Brush, G.J. (1869) A System of Mineralogy, 5th ed. Wiley.Suche in Google Scholar

Darwin, C.G. (1914) The theory of X-ray reflexion. Philosophical Magazine, 27, 315–333 and 675–690.Suche in Google Scholar

Debye, P. (1913) Über den Einfluss der Wärmebewegung auf die Interferenzers- cheinungen bei Röntgenstrahlen, Verhandlungen der Deutschen Physikalischen Gesellschaft, 15, 678–689.Suche in Google Scholar

Debye, P., and Scherrer, P. (1916) Interferenz an regellos orientierten Teilchen im Röntgenlicht. I. Physikalische Zeitschrift, 17, 277–283.Suche in Google Scholar

Drits V.A. (1987) SAED and HREM study of order/disorder and structural heterogeneity in layer minerals. In V.A. Drits, Ed., Electron Diffraction and High-Resolution Electron Microscopy of Mineral Structures, p. 217–238. Springer.10.1007/978-3-642-71729-1_11Suche in Google Scholar

Eakle, A.S. (1926) Needed extension in mineralogic instruction. American Min- eralogist, 11, 45–52.Suche in Google Scholar

Eckert, M. (2012) Disputed discovery: the beginnings of X-ray diffraction in crystals in 1912 and its repercussions. Acta Crystallographica Section A: Foundations of Crystallography, 68(1), 30–39.10.1524/zkri.2012.1445Suche in Google Scholar

Ewald, P.P. (1913) Zur Theorie der Interferenzen der Röntgenstrahlen in Kristallen. Physikalische Zeitschrift, 14, 465–472.Suche in Google Scholar

Fleck, G.M. (1963) Atomism in late nineteenth-century physical chemistry. Journal of the History of Ideas, 24, 106–114.10.2307/2707861Suche in Google Scholar

Ford, W.E., and Bradley, W.M. (1916a) Margarosanite, a new lead-calcium silicate from Franklin, New Jersey. American Journal of Science, 248, 159–162.10.2475/ajs.s4-42.248.159Suche in Google Scholar

Ford, W.E., and Bradley, W.M. (1916b) On hydro-zincite. American Journal of Science, 247, 59–62.10.2475/ajs.s4-42.247.59Suche in Google Scholar

Forman, P. (1969) The discovery of the diffraction of X-rays by crystals; a critique of the myths. Archive for History of Exact Sciences, 6, 38–71.10.1007/BF00327262Suche in Google Scholar

Frankenheim, M.L. (1826) Crystallonomische Aufsätze. ISI Enzyklopadische Zeitung Oken, 5, 497–515 and 542–565.Suche in Google Scholar

Friedel, G. (1913) Sur les symmetries cristallines que peut reveler la diffraction des rayons Röntgen. Comptes Rendus de l’Académie des Sciences, 157, 1533–1536.Suche in Google Scholar

Friedrich, W., Knipping, P., and von Laue, M.T.F. (1912) interferenz-Erscheinungen bei Röntgenstrahlen. Sitzungsberichte der Mathematischen-Physikalischen Klasse der Königlich Bayerischen Akademie der Wissenschaften zu München, p. 303–322.Suche in Google Scholar

Friedrich, W., Knipping, P., and Laue, M. (1913) Interferenzerscheinungen bei roentgenstrahlen. Annalen der Physik, 346, 971–988.10.1002/andp.19133461004Suche in Google Scholar

Gadolin, A.V. (1867) Deduction of all crystallographic systems and their subdivisions by means of a single general principle. Annals of the Imperial St Peters- burg Mineralogical Society Series 2, 4, 112–200. (In Russian)Suche in Google Scholar

Geiger, C.A. (2016) A tale of two garnets: The role of solid solution in the develop- ment toward a modern mineralogy. American Mineralogist, 101, 1735–1749.10.2138/am-2016-5522Suche in Google Scholar

Gibbs, J.W. (1902) Elementary Principles in Statistical Mechanics Developed with Especial Reference to the Rational Foundation of Thermodynamics. Scribner’s Sons, New York.10.5962/bhl.title.32624Suche in Google Scholar

Gibson, C.S. (1941) Sir William Jackson Pope 1870–1939. Obituary Notices of Fellows of the Royal Society, 3, 291–324.10.1098/rsbm.1941.0004Suche in Google Scholar

Goltrant, O., Cordier, P., and Doukhan, J.C. (1991) Planar deformation features in shocked quartz; a transmission electron microscopy investigation. Earth and Planetary Science Letters, 106, 103–115.10.1016/0012-821X(91)90066-QSuche in Google Scholar

Gordin, M.D. (2019) A Well-Ordered Thing: Dmitrii Mendeleev and the Shadow of the Periodic Table. Princeton University Press.10.1515/9780691184425Suche in Google Scholar

Gordon, S.G. (1917) Proceedings of Societies. American Mineralogist, 2, 68.Suche in Google Scholar

Grabowski, J.J. (1992) Sports in Cleveland: an illustrated history. Case Western Reserve University, Cleveland.Suche in Google Scholar

Greene, J.C., and Burke, J.G. (1978) The science of minerals in the age of Jefferson. Transactions of the American Philosophical Society, 68, 1–113.10.2307/1006294Suche in Google Scholar

Grossman, M. I. (2017) John Dalton and the origin of the atomic theory: reassessing the influence of Bryan Higgins. The British Journal for the History of Science, 50, 657–676.10.1017/S0007087417000851Suche in Google Scholar PubMed

Groth, P. (1906) An Introduction to Chemical Crystallography. Wiley.Suche in Google Scholar

Gruner, J.W. (1928) The oscillation method of X-ray analysis of crystals. American Mineralogist, 3, 123–141.Suche in Google Scholar

Guggenheim, S., and Eggleton, R.A. (1988) Crystal chemistry, classification, and identification of modulated layer silicates. Reviews in Mineralogy and Geochemistry, 19, 675–725.10.1515/9781501508998-022Suche in Google Scholar

Hales, T.C. (2005) A proof of the Kepler conjecture. Annals of Mathematics, 1065–1185.10.4007/annals.2005.162.1065Suche in Google Scholar

Hausmann, J.F.L. (1813) Handbuch der Mineralogie, 3 vol., 2nd ed., pp. 302. Göttingen.Suche in Google Scholar

Haüy, R.J. (1784) Essai d’une Théorie sur la structure des Crystaux. Gogué and Née de la Rochelle, Paris.Suche in Google Scholar

Haüy, R.J. (1801) Traité de Minéralogie. Council of Mines, Paris.Suche in Google Scholar

Heaney, P.J. (2016) Time’s arrow in the trees of life and minerals. American Mineralogist, 101, 1027–1035.10.2138/am-2016-5419Suche in Google Scholar

Hessel, J.F.C. (1830) Krystall. In Gehler’s Physikalisches Wörterbuch, 5, 1023-1360. Schwickert, Leipzig. Reprinted in W.F. Ostwald (1897). Klassiker der exacten Wissenschaften, 89, 41–124.Suche in Google Scholar

Hochella, M.F., Lower, S.K., Maurice, P.A., Penn, R.L., Sahai, N., Sparks, D.L., and Twining, B.S. (2008) Nanominerals, mineral nanoparticles, and Earth systems. Science, 319, 1631–1635.10.1126/science.1141134Suche in Google Scholar

Hooke, R. (1665) Micrographia: or some physiological descriptions of minute bodies made by magnifying glasses with observations and inquiries made thereupon. Jo. Martyn and Ja. Allestry, Royal Society, London.10.5962/bhl.title.904Suche in Google Scholar

Hooker, M., and Montgomery, A. (1975) Edgar Theodore Wherry. American Mineralogist, 60, 533–539.Suche in Google Scholar

Hull, A.W. (1917a) A new method of X-ray crystal analysis. Physical Review, 10, 661–697.10.1103/PhysRev.10.661Suche in Google Scholar

Hull, A.W. (1917b) The crystal structure of iron. Physical Review, 9, 84–87.10.1016/S0016-0032(17)90316-3Suche in Google Scholar

Hull, A.W. (1922) The crystal structures of the common elements. Journal of the Franklin Institute, 189–216.10.1016/S0016-0032(22)90790-2Suche in Google Scholar

Hull, A.W. (1946) Thirty years of X-ray research at the General Electric Research Laboratory. American Journal of Physics, 14, 71–79.10.1119/1.1990804Suche in Google Scholar

Hunt, W.F. (1955) Edward Henry Kraus. American Mineralogist, 40, 945–951.Suche in Google Scholar

Hunt, W.F., and Kraus, E.H. (1916) Note on the variable composition of melanochalcite. American Journal of Science, 242, 211–214.10.2475/ajs.s4-41.242.211Suche in Google Scholar

Hunter, G.K. (2004). Light is a messenger: the life and science of William Lawrence Bragg. Oxford University Press.10.1093/acprof:oso/9780198529217.001.0001Suche in Google Scholar

Huygens, C. (1690) Traité de la lumière. Pieter van der Aa, Leiden.Suche in Google Scholar

James, R.W. (1948). The Optical Principles of the Diffraction of X-rays. G. Bell and Sons, London.Suche in Google Scholar

Kaji, M. (2002) D.I. Mendeleev’s concept of the chemical elements and The Principles of Chemistry. Bulletin for the History of Chemistry, 27, 4–16.Suche in Google Scholar

Kargon, R. (1965) Mendeleev’s chemical ether, electrons, and the atomic theory. Journal of Chemical Education, 42, 388–389.10.1021/ed042p388Suche in Google Scholar

Kean, S. (2011) The Disappearing Spoon. Little, Brown, and Company, New York.Suche in Google Scholar

Kepler, J. (1611) Strena seu de nive sexangula. Gottfried Tampach, Franfurt.Suche in Google Scholar

Kolata, D.R., Huff, W.D., and Bergstrom, S.M. (1996). Ordovician K-bentonites of eastern North America (Vol. 313). Geological Society of America.10.1130/0-8137-2313-2Suche in Google Scholar

Kraus, E.H. (1919) Crystallographical and Mineralogical Society of America. Science, 50, 497.10.1126/science.50.1300.497.aSuche in Google Scholar

Kraus, E.H. (1921) The future of mineralogy in America. American Mineralogist, 6, 23–34.10.1126/science.53.1367.219Suche in Google Scholar PubMed

Kraus, E.H. (1934) Memorial of Frank Robertson Van Horn. American Mineralogist, 19, 101–105.Suche in Google Scholar

Kraus, E.H., and Hunt, W.F. (1920). Mineralogy: An Introduction to the Study of Minerals and Crystals. McGraw-Hill.Suche in Google Scholar

Kraus, E.H., Phillips, A.N., van Horn, F.R., Walker, T.L., Wherry, E.T., and Whit- lock, H.P. (1919) Crystallographical and Mineralogical Society of America. Science, 50, 497.10.1126/science.50.1300.497.aSuche in Google Scholar

Kubbinga, H. (2012) Crystallography from Haüy to Laue: Controversies on the molecular and atomistic nature of solids. Acta Crystallographica, A68, 3–29.10.1524/zkri.2012.1459Suche in Google Scholar

Kuhn, T. (1996) The Structure of Scientific Revolutions. University of Chicago Press.10.7208/chicago/9780226458106.001.0001Suche in Google Scholar

Lalena, J.N. (2006) From quartz to quasicrystals: probing nature’s geometric patterns in crystalline substances. Crystallography Reviews, 12, 125–180.10.1080/08893110600838528Suche in Google Scholar

Langmuir, I. (1919) The arrangement of electrons in atoms and molecules. Journal of the American Chemical Society, 41, 868–934.10.1021/ja02227a002Suche in Google Scholar

Levison, W.G. (1917) Proceedings of Societies. American Mineralogist, 2, 67–68.Suche in Google Scholar

Lewis, G.N. (1908) The osmotic pressure of concentrated solutions, and the laws of the perfect solution. Journal of the American Chemical Society, 30, 668–683.10.1021/ja01947a002Suche in Google Scholar

Lewis, G.N. (1916) The atom and the molecule. Journal of the American Chemical Society, 38, 762–785.10.1021/ja02261a002Suche in Google Scholar

Lewis, G.N. (1926) The conservation of photons. Nature, 118, 874–875.10.1038/118874a0Suche in Google Scholar

Lima-de-Faria, J. (1990) Time-maps of crystallography. In Lima-de-Faria, Ed., Historical Atlas of Crystallography, pp. 5–42. Kluwer.Suche in Google Scholar

Lindley, D. (2015) Boltzmann’s Atom: The Great Debate that Launched a Revolution in Physics. The Free Press, New York.Suche in Google Scholar

Mach, E. (1883) Die Mechanik ihrer Entwicklung. F.A. Brockhaus, Leipzig.Suche in Google Scholar

Mach, E. (1919) The Science of Mechanics. Trans. McCormack, T.J. Open Court Publishing, Chicago.Suche in Google Scholar

Madelung, E. (1909) Molekulare Eigenschwingungen. Nachrichten von der Gesellschaft der Wissenschaften zu Göttingen, Mathematisch-Physikalische Klasse, 100–106.Suche in Google Scholar

McLaren, A.C. (1991) Transmission electron microscopy of minerals and rocks. Cambridge University Press.10.1017/CBO9780511529382Suche in Google Scholar

Melhado, E.M. (1980) Mitscherlich’s discovery of isomorphism. Historical Studies in the Physical Sciences, 11, 87–123.10.2307/27757472Suche in Google Scholar

Melhado, E.M. (1981) Jacob Berzelius: The Emergence of his Chemical System. University of Wisconsin Press, Madison. Cambridge University Press.Suche in Google Scholar

Melhado, E.M. and Frdngsmyr, T., Eds. (2003) Enlightenment science in the romantic era: The chemistry of Berzelius and its cultural setting (vol. 10). Cambridge University Press.Suche in Google Scholar

Mendeleev, D. (1879) The periodic law of the chemical elements. The Chemical News, 40, no. 1042.Suche in Google Scholar

Mendeleev, D. (1891) Principles of Chemistry, Vol 1. Translated by G. Kamensky, Long- mans, Green & Co., London.Suche in Google Scholar

Michel, F.M., Ehm, L., Antao, S.M., Lee, P.L., Chupas, P.J., Liu, G., Strongin, D.R., Schoonen, M.A., Phillips, B.L., and Parise, J.B. (2007) The structure of ferrihydrite, a nanocrystalline material. Science, 316, 1726–1729.10.1126/science.1142525Suche in Google Scholar PubMed

Miers, H.A. (1902) Mineralogy: An Introduction to the Scientific Study of Minerals. MacMillan and Co., London.Suche in Google Scholar

Miers, H.A. (1918) The old and the new mineralogy. Journal of the Chemical Society, Transactions, 113, 363–386.10.1039/ct9181300363Suche in Google Scholar

Mitscherlich, E. (1819) Über die Kristallisation der Salze, in denen das Metall der Basis mit zwei Proportionen Sauerstoff verbunden ist. Abhandlungen, Akademie der Wissenschaften, Berlin, pp. 427–437.Suche in Google Scholar

Mitscherlich, E. (1821) Über das Verhältniss zwischen der chemischen Zusammensetzung und der Krystallform arseniksaurer und phosphorsaurer Salze. W. Engelmann, Leipzig.Suche in Google Scholar

Mitscherlich, E. (1822) Sur la relation qui existe entre la forme crystalline et les proportions chimiques. I. Mémoire sur les arseniates et les phosphates. Annales des Chimie et des Physique 19, 350–419.Suche in Google Scholar

Montgomery, A. (1951) Peter Zodac and Rocks and Minerals. Rocks & Minerals, 26, 451–453.10.1080/00357529.1951.11768228Suche in Google Scholar

Moore, D.M., and Reynolds, R.C. Jr. (1997) X-ray Diffraction and the Identification and Analysis of Clay Minerals. 2nd ed., Oxford University Press.Suche in Google Scholar

Moore, P.B. (1990) Brief history of chemical crystallography. I. Inorganic com- pounds. In Lima-de-Faria, Ed., Historical Atlas of Crystallography, Kluwer Academic Publishers, Dordrecht, pp. 5–42.Suche in Google Scholar

Morrow, S.I. (1969) One hundred and fifty years of isomorphism. Journal of Chemical Education, 46, 580–583.10.1021/ed046p580Suche in Google Scholar

Moseley, H.G.J. (1913) The high-frequency spectra of the elements. Philosophical Magazine, 26, 1024–1034.Suche in Google Scholar

Moses, A.J., and Parsons, C.L. (1900) Elements of Mineralogy, Crystallography and Blowpipe Analysis. 2nd ed. D. Van Nostrand Company, New York.Suche in Google Scholar

Moses, A.J., and Parsons, C.L. (1916) Elements of Mineralogy, Crystallography and Blowpipe Analysis, 5th ed. Nostrand Company, New York.Suche in Google Scholar

Navrotsky, A. (2004) Energetic clues to pathways to biomineralization: Precursors, clusters, and nanoparticles. Proceedings of the National Academy of Sciences, 101, 12,096–12,101.10.1073/pnas.0404778101Suche in Google Scholar PubMed PubMed Central

Neumeier, G. A brief history of mineral magazines. Newsletter of the New York Mineralogical Club. http://www.newyorkmineralogicalclub.org/history/min-utes/Introduction%20-%20A%20Brief%20History%20of%20Mineral%20Magazines.pdfSuche in Google Scholar

Niaz, M., Rodríguez, M.A., and Brito, A. (2004) An appraisal of Mendeleev’s contribution to the development of the periodic table. Studies in the History and Philosophy of Science, 35, 271–282.10.1016/j.shpsa.2003.12.014Suche in Google Scholar

Nieto, F. and Livi, K.J., Eds. (2013) Minerals at the Nanoscale (vol. 14). The Mineralogical Society of Great Britain and Ireland.10.1180/EMU-notes.14Suche in Google Scholar

Notes and News (1946) The Crystallographic Society. American Mineralogist, 31, 84.Suche in Google Scholar

O’Day, P.A., Rehr, J.J., Zabinsky, S.I., and Brown, G.J. (1994) Extended X-ray absorption fine structure (EXAFS) analysis of disorder and multiple-scattering in complex crystalline solids. Journal of the American Chemical Society, 116, 2938–2949.10.1021/ja00086a026Suche in Google Scholar

Ostwald, W. (1904) Faraday Lecture: Elements and compounds. Journal of the Chemical Society, Transactions, 85, 506–522.10.1039/ct9048500506Suche in Google Scholar

Parsons, A.L. (1943) Memorial of Thomas Leonard Walker. American Mineralogist, 28, 167–173.Suche in Google Scholar

Pauling, L. (1929) The principles determining the structure of complex ionic crystals. Journal of the American Chemical Society, 51, 1010–1026.10.1021/ja01379a006Suche in Google Scholar

Perutz, M.F. (1990) How W.L. Bragg invented X-ray analysis. Acta Crystallographica, A46, 633–643.10.1107/S010876739000410XSuche in Google Scholar

Pfeiffer, P. (1917) Crystals as molecular compounds. Zeitschrift für anorganische chemie, 97, 161–174.10.1002/zaac.19160970112Suche in Google Scholar

Phair, G. (1969a) The American Mineralogist: Its first four years. American Min- eralogist, 54, 1233–1243.Suche in Google Scholar

Phair, G. (1969b) The founding of the Mineralogical Society of America. American Mineralogist, 54, 1244–1255.Suche in Google Scholar

Phillips, A.H. (1912) Mineralogy: An Introduction to the Theoretical and Practical Study of Minerals. MacMillan, New York.10.5962/bhl.title.19221Suche in Google Scholar

Phillips, A.H. (1916) New zinc phosphates from Salmo, B.C. American Journal of Sci- ence, 249, 275–278.10.2475/ajs.s4-42.249.275Suche in Google Scholar

Pojman, P. (2011) Ernst Mach. In Zalta, E.N., Ed., The Stanford Encyclopedia of Philosophy. URL: <https://plato.stanford.edu/archives/win2011/entries/ernst-mach/>.Suche in Google Scholar

Pope, W.J. (1935) William Barlow 1845-1934. Obituary Notices of Fellows of the Royal Society, 1, 367–370.10.1098/rsbm.1935.0001Suche in Google Scholar

Pough, F.H. (1949) Memorial of Herbert Percy Whitlock. American Mineralogist, 34, 261–266.Suche in Google Scholar

Rhodes, R. (1986) The Making of the Atomic Bomb. Simon and Schuster.Suche in Google Scholar

Rogers, A.F. (1921) Introduction to the Study of Minerals and Rocks. McGraw-Hill Book Co.Suche in Google Scholar

Rutherford, E. (1911) The scattering of α and β particles by matter and the structure of the atom. Philosophical Magazine, 21, 669–688.10.1016/B978-0-08-012102-4.50015-2Suche in Google Scholar

Senechal, M. (1990) Brief history of geometrical crystallography. In Lima-de-Faria, Ed., Historical Atlas of Crystallography, Kluwer Academic Publishers, Dordrecht, pp. 43–59.Suche in Google Scholar

Smits, A., and Scheffer, F.E.C. (1917) The interpretation of the “Roentgenograms” and Roentgen spectra of crystals. Proceedings of the Koninklijke Akademie van Wetenschappen te Amsterdam, 19, 432–438.Suche in Google Scholar

Solly, R.H. (1894) An Elementary Introduction to Mineralogy. C.J. Clay and Sons, London.Suche in Google Scholar

Sohncke, L. (1888). Erweiterung der Theorie der Krystallstructur. Zeitschrift für Kristallographie-Crystalline Materials, 14, 426–446.10.1524/zkri.1888.14.1.426Suche in Google Scholar

Stockwell, C.H. (1927) An X-ray study of the garnet group. American Mineralogist, 12, 327–344.Suche in Google Scholar

Taber, S. (1916) The growth of crystals under external pressure. American Journal of Science, 246, 532–556.10.2475/ajs.s4-41.246.532Suche in Google Scholar

Thomson, J.J. (1904) On the structure of the atom: an investigation of the stability and periods of oscillation of a number of corpuscles arranged at equal intervals around the circumference of a circle; with application of the results to the theory of atomic structure. Philosophical Magazine, 7, 237–265.10.1080/14786440409463107Suche in Google Scholar

Turner, S., and Buseck, P.R. (1979) Manganese oxide tunnel structures and their intergrowths. Science, 203, 456–458.10.1126/science.203.4379.456Suche in Google Scholar PubMed

Van Melsen, A.G. (1960) From atomos to atom: the history of the concept atom. Harper and Brothers, New York.Suche in Google Scholar

Van Tendeloo, G., Van Landuyt, J., and Amelinckx, S. (1976) The α→β phase transition in quartz and AlPO₄ as studied by electron microscopy and diffraction. Physica status solidi (a), 3, 3, 723–735.10.1002/pssa.2210330233Suche in Google Scholar

Veblen, D.R. (1983) Microstructures and mixed layering in intergrown wonesite, chlorite, talc, biotite, and kaolinite. American Mineralogist, 68, 566–580.Suche in Google Scholar

Veblen, D.R., and Buseck, P.R. (1979) Chain-width order and disorder in biopyriboles. American Mineralogist, 64, 687–700.Suche in Google Scholar

von Laue, M. (1912) Eine quantitative Prüfung der Theorie für die Interferenz-Erscheinungen bei Röntgenstrahlen. Verlag der Königlichen Bayerische Akademie der Wissenschaften, 363–373.Suche in Google Scholar

von Laue, M. (1962) My development as a physicist: An autobiography. In Ewald, P.P., Ed., Fifty Years of X-ray Diffraction, pp. 278–307. International Union of Crystallography, Glasgow.10.1007/978-1-4615-9961-6_17Suche in Google Scholar

Walker, T.L. (1923) The development of mineralogical methods. American Min- eralogist, 8, 41–46.Suche in Google Scholar

Washington, H.S. (1925) The modern study of minerals. American Mineralogist, 10, 45–52.Suche in Google Scholar

Weiss, C.S. (1814) Uebersichliche Darstellung des verschie—denen naturlichen Abteilungen der Kristallisationssysteme. Abhandlungen der Koniglichen Akademie der Wissenschaften in Berlin, 289–344.Suche in Google Scholar

Wenk, H.-R., Ed. (1976) Electron Microscopy in Mineralogy. Springer-Verlag.10.1007/978-3-642-66196-9Suche in Google Scholar

Wherry, E.T. (1917a) Clay derived from volcanic dust in the Pierre in South Dakota. Journal of the Washington Academy of Sciences, 7, 576–583.Suche in Google Scholar

Wherry, E.T. (1917b) Review of two recent papers on crystal structure. American Mineralogist, 2, 36–38.Suche in Google Scholar

Wherry, E.T. (1918) Abstracts of crystallographic literature. American Mineralogist, 3, 137–147.Suche in Google Scholar

Wherry, E.T. (1925) Bentonite as a one-dimensional colloid. American Mineralogist, 10, 120–123.Suche in Google Scholar

Whitlock, H.P. (1920) The Mineralogical Society of America. Science, 51, 219–220.10.1126/science.51.1313.219Suche in Google Scholar PubMed

Wollaston, W.H. (1812) On the primitive crystals of carbonate of lime, bitter-spar, and iron-spar. Philosophical Transactions of the Royal Society of London, 102, 159–162.10.1080/14786441208638166Suche in Google Scholar

Wollaston, W.H. (1813) The Bakerian Lecture: On the elementary particles of certain crystals. Philosophical Transactions of the Royal Society of London, 103, 51–63.10.1080/14786441308638283Suche in Google Scholar

Wooster, W.A. (1990) Brief history of physical crystallography. In J. Lima-de-Faria, Ed., Historical Atlas of Crystallography, pp. 61–75. Kluwer.Suche in Google Scholar

Wyckoff, R.W.G. (1920) The crystal structures of some carbonates of the calcite group. American Journal of Science, 299, 317–360.10.2475/ajs.s4-50.299.317Suche in Google Scholar

Wyckoff, R.W.G. (1921) The crystal structure of alabandite (MnS). American Journal of Science, 11, 239–249.10.2475/ajs.s5-2.11.239Suche in Google Scholar

Wyckoff, R.W.G. (1925) Crystal structure of high temperature cristobalite. American Journal of Science, 54, 448–459.10.2475/ajs.s5-9.54.448Suche in Google Scholar

Wyckoff, R.W.G. (1954) Some thoughts on the future of natural science, with illustrations from the growth of X-ray diffraction work in the United States. British Journal of Applied Physics, 5, 199–204.10.1088/0508-3443/5/6/301Suche in Google Scholar

Wyckoff, R.W.G. (1962) Reminiscences. In P.P. Ewald, Ed., Fifty Years of X-ray Diffraction. International Union of Crystallography, Glasgow. pp. 691–694.10.1007/978-1-4615-9961-6_72Suche in Google Scholar

Wyckoff, R.W.G., and Merwin, H.E. (1924) The crystal structure of dolomite. American Journal of Science, 48, 447–461.10.2475/ajs.s5-8.48.447Suche in Google Scholar

Wyckoff, R.W., Merwin, H.E., and Washington, H.S. (1925) X-ray diffraction measurements upon the pyroxenes. American Journal of Science, 59, 383–397.10.2475/ajs.s5-10.59.383Suche in Google Scholar

Received: 2019-07-12

Accepted: 2019-09-03

Published Online: 2019-12-30

Published in Print: 2020-01-28

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https://doi.org/10.2138/am-2020-7205

Schlagwörter für diesen Artikel

Mineralogical Society of America; mineralogy; crystallography; X-ray diffraction; history of science; Invited Centennial article; Review