The mathematical apparatus of simulation diffraction by spiral nanotubes of arbitrary chemical composition, whose structure is described with the use of Bravais cells, is developed. The case of electron microdiffraction by a single nanotube is considered, the distributions of intensity in layer planes and lengthways layer lines are calculated.
[1] http://ntrs.nasa.gov/search.jsp?R=20120012923
[2] http://tfy.tkk.fi/nanomat/PDF%20publications/cm300308k.pdf
[3] http://www.chalcogen.infim.ro/33_Buang.pdf
[4] Nasyrov I., Pashin D., Khalitov Z. and Valeeva D.: Sci. Israel-Techn. Adv., 2010, 12, 63.
[5] Jagodzinski H. and Kunze G.: News Jb. Mineral. Mh., 1954, 95.
[6] Whittaker E.: Acta Cryst., 1955, 8, 265.
[7] Galimov E. and Khalitov Z.: Modelirovanie Difrakcii Nanotrubkami. Izd-vo Kazan. Gos. Techn. Univ., Kazan 2007.
[8] Radovsky G., Popovitz-Biro R., Staiger M. et al.: Angew. Chem. Intl. Edn., 2011, 50, 12316.
[9] Figovsky O., Pashin D., Nasyrov I. et al.: Chem. & Chem. Techn., 2012, 6, 43.
[10] Figovsky O., Pashin D., Khalitov Z. et al.: Chem. & Chem. Techn., 2012, 6, 167.
[11] Gricaenko G., Zviagin B., Boiarskaia R. et al.: Metody Elektronnoi Microskopii Mineralov. Nauka, Moskwa 1969.
[12] Wittaker E.: Acta Cryst., 1967, 10, 149.