7/14/2023 0 Comments Bragg diffractionNobel Foundation (1967) Nobel Lectures including presentation speeches and laureates’ biographies. Originally published in Laue MV (1961) vol. Laue MV (1962) My Development as a Physicist. Laue MV (1961) Gesammelte Schriften und Vortrage. Laue MV (1915) Concerning the detection of X-ray interferences. In: Enzyklopedie der Mathematischen Wissenschaften, vol 5. Mit Anwendung auf die Messung der Schwärzungsverteilung in einigen mit Röntgenstrahlen aufgenommenen Spalphotogrammen von Walter und Pohl. Koch PP (1913) Über die Messung der Schwärzung photographischer Platten in sehr schmalen Bereichen. Haga H, Wind CH (1899) Die Beugung der Röntgenstrahlen. Akademie der Wissenschaften zu Munchen 42:303–322įriedrich W, Knipping P, Laue M v (1912b) Sealed note deposited with the Bavarian Academy of Science on May 4, 1912. Sitzungsberichte der mathematisch-physikalischen Classe. Reprinted in pdf format for the IUCr XVIII Congress, Glasgow, Scotland, Copyright© 1962, 1999 International Union of Crystallographyįriedrich W, Knipping P, Laue M v (1912a) Interferenz-Erscheinungen bei Röntgenstrahlen. Oosthoeks Uitgeversmaaatschappij, Utrecht. Phil Trans R Soc Lond 171:65–116Įwald PP (ed.) (1962) Fifty Years of X-ray diffraction. Gauthier-Villars, Parisīragg WH to Rutherford E (1912) Rutherford papers, Cambridge University Libraryĭe La Rue W, Muller HW (1880) Experimental researches on the electric discharge with the chloride of silver battery. Bell, Londonīragg WH, Bragg WL (1921) Rayons X et structure cristalline (French translation of the 3rd edition of Bragg and Bragg 1915). Proc Roy Soc London 88A:428–438īragg WH, Bragg WL (1915) X-rays and crystal structure. Proc Roy Soc London 89A:248–277īragg WH, Bragg WL (1913) The reflection of X-rays by crystals. Proc Cambridge Phil Soc 17:43–57 (read 11 November 1912)īragg WL (1913c) The structure of some crystals as indicated by their diffraction of X-rays. Nature 90:572īragg WL (1913b) The diffraction of short electromagnetic waves by a crystal. Nature 90:410īragg WH (1913a) X-rays and crystals. Nature 90:360–361īragg WL (1912b) The specular reflection of X-rays. Trans Roy Soc South Australia 31:79–93īragg WH (1912a) X-Rays and Crystals. Phil Mag 22:397–412īragg WH (1907) A comparison of some forms of electric radiation. Phil Mag 15:288–296īarkla CG (1911) The spectra of the fluorescent Roentgen radiations. Proc Roy Soc London 77A:247–255īarkla CG (1908) Note on X-rays and scattered X-rays. Bragg), and represented a solid reference point for the project of Laue.īarkla CG (1906) Polarization in secondary Röntgen radiation. These works strengthened the hypothesis of the wave nature of X-rays, at the expense of the “corpuscular hypothesis” (supported notably by J. Barkla on X-ray absorption, which resulted in the discovery in 1906 of the Roentgen characteristic radiation of the elements. Particular attention will be given to the works of C. Laue’s discovery of X-ray diffraction was immediately taken up by William Henry Bragg and re-interpreted by his son William Lawrence in terms of X-ray reflection by the planes of the crystal, thus becoming, in a few months, a formidable tool for the study of crystal structures, as well as for the precise determination of the wavelengths of X-rays (to Bragg father we owe the construction of the first X-ray ionization spectrometer). Knipping, with the theoretical interpretation given to them by Laue. Then we will discuss the feasibility of the Laue project, as well as the realization of the experiment, and the first results of W. This value was at the base, together with the adoption of the space-lattice model for the crystal, of Laue idea of using a crystal as a diffraction grating for X-ray. Sommerfeld to achieve, at the beginning of 1912, a qualitative estimate of the wavelength of X-rays around 4 × 10 −9 cm. Starting from the discovery of Roentgen’s X-ray (Röntgen 1895), I here reconstruct the various attempts carried out to find X-ray diffraction using very thin wedge-shaped slits.
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