![]() ![]() J., Clifton, I., Zurek, S., Gover, S., Johnson, L. I, 1985, Information Quarterly for Protein Crystallography, Daresbury Laboratory, 15: 17. Results and recommendations for the processing of synchrotron radiation data in macromolecular crystallography, J. L., 1986, Oscillation camera data processing. P., 1983, X-ray optics and spectral brightness of the superconducting SRS wiggler, Nucl. Klasse, ( Kgl.) Bayerische Akademie der Wissenschaften, Munchen, 303–322. USA, 85: 112.įriedrich, W., Knipping, P., and Laue, M. A., and Hajdu, J., 1988, X-ray Laue diffraction from crystals of xylose isomerase, Proc. R., and Moffat, K., 1987, Multiplicity distribution of reflections in laue diffraction, Acta Cryst., A43: 656.Įlder, M., 1986, Information Quarterly for Protein Crystallography, Dares-bury Laboratory, 19: 31.įarber, G. Congiu Castellano, eds., Springer Verlag, Berlin, Heidelberg, New York, London, Paris, Tokyo, 2: 52.Ĭruickshank, D. M., 1987, in: “Springer Series in Biophysics, Biophysics and Synchrotron Radiation,” A. R., Habash, J., Hajdu, J., and Harding, M. W., Moffat, K., and Helliwell, 1986, Information Quarterly for Protein Crystallography, Daresbury Laboratory, 18: 23.Ĭampbell, J. W., 1968, The optimum strategy in measuring structure factors, Acta Cryst., B24: 1355.īricogne, C., 1976, Methods and programs for direct-space exploitation of geometric redundancies, Acta Cryst., A32: 832.Ĭampbell, J. J., and Canut de Amoros, M., 1975, “The Laue Method,” Academic Press, New York.Īrndt, U. This process is experimental and the keywords may be updated as the learning algorithm improves.Īmoros, J. These keywords were added by machine and not by the authors. The Laue technique did not become a method of data collection because conventional X-ray sources do not have a satisfactory spectrum and because of the difficulties in unravelling the complicated diffraction patterns. Moreover, with crystals of high symmetry, a full data set may be recorded on a single photograph. The wider the wavelength range the more lattice planes become accessible to the Laue geometry (Amoros et al., 1975 Cruickshank et al., 1987). With a stationary crystal and white X-radiation, a large number of lattice planes diffract simultaneously as the Bragg condition is satisfied for each of these planes by at least one wavelength of the spectrum. His copiously illustrated historical account is based as much on scientific material as on private correspondence, creating a fascinating and convincingly detailed portrait.Seventy-six years ago, Friedrich, Knipping and von Laue (1912) demonstrated the diffraction of X-rays on a crystal of copper sulphate using white X-radiation. Jost Lemmerich could hardly have been better equipped to describe German physics and physicists in the 1920s. It is thus surprising that this is the first extensive biography of this famous scientist. Laue may be counted among the few persons of influence in Germany who – as Einstein put it – managed to “stay morally upright” under Nazism. As an early supporter of Einstein’s relativity theory, he published fundamental papers on light scattering as well as on matter waves and superconductivity. This major advance for research on solids earned him the Nobel Prize two years later, the ultimate acclaim as an exceptional theoretician. The discovery by Max von Laue in 1912 of interference effects demonstrated the wave-like nature of X-rays and the atomic lattice structure of crystals. This biography gives an insider view of 20th century German science in the making. ![]()
0 Comments
Leave a Reply. |
AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |