References
- Gromov VЕ, Yuriev AB, Morozov KV, et al. Microstructure of hardened rails. Cambridge: CISP; 2015.
- Vorozhishchev VI: The composition and production technology of the rails increased efficiency, Novokuznetsk, Izd-vo “Novokuznetskii poligraficheskii kombinat”; 2008.
- Shur EA. Damage to the rails. Moscow: Intekst; 2012.
- Sheinman E. Wear of rails. A review of the American press. J Friction Wear. 2012;33:308–314.
- Ivanisenko Y, Fecht HJ. Mechanical behavior of nano crystalline palladium at high strains and high strain rates. Steel Technol. 2008;3:19–23.
- Ivanisenko Y, Maclaren I, Sauvage X, et al. Shear-induced alpha → gamma transformation in nanoscale Fe-C composite. Acta Mater. 2006;54:1659–1669.
- Ning JL, Courtois-Manara E, Kurmanaeva I, et al. Tensile properties and work hardening behaviors of ultrafine grained carbon steel and pure iron processed by warm high pressure torsion. Mater Sci Eng A. 2013;581:8–15.
- Gavriljuk VG. Decomposition of cementite in pearlitic steel due to plastic deformation. Mater Sci Eng A. 2003;345:81–89.
- Li YJ, Choi P, Borchers C, et al. Atomic-scale mechanisms of deformation-induced cementite decomposition in pearlite. Acta Mater. 2011;59:3965–3977.
- Gavriljuk VG: Comment on “Effect of interlamellar spacing on cementite dissolution during wire drawing of pearlitic steel wires”. Scripta Mater. 2001;45:1469–1472.
- Rybin VV. Large plastic deformation and fracture of metals. Moscow: Metallurgiya; 1986.
- Gromov VE, Petrunin VA. Localization of plastic-deformation under conditions of electro-stimulated drawing. Phys Status Solidi. 1993;139:77–84.
- Ivanisenko Y, Lojkowski W, Fecht HJ. Stress and strain induced phase transformations in pearlitic steels. Mater Sci Forum. 2007;539–543:4681–4686.
- Ivanisenko Y, Wunderlich RK, Valiev RZ, et al. Annealing behaviour of nanostructured carbon steel produced by severe plastic deformation. Scripta Mater. 2003;49:947–952.
- MacLaren I, Ivanisenko Y, Fecht H-J, et al. Early stages of nanostructuring of a pearlitic steel by high pressure torsion deformation. In: Zhu E.T. et al., editor. Ultrafine grained materials IV. San Antonio: The Minerals, Metals & Materials Society; 2006. p. 1–6.
- Kumar KS, Van Swygenhoven H, Suresh S. Mechanical behavior of nanocrystalline metals and alloys. Acta Mater. 2003;51:5743–5774.
- Ivanisenko Y, Lojkowski W, Valiev RZ, et al. The mechanism of formation of nanostructure and dissolution of cementite in a pearlitic steel during high pressure torsion. Acta Mater. 2003;51:5555–5570.
- Meyers MA, Mishra A, Benson DJ, et al. Mechanical properties of nanocrystalline materials. Prog Mater Sci. 2006;51;427–556.
- Ivanov YF, Gromov VE, Peregudov OA, et al. Degradation of rail-steel structure and properties of the surface layer. Steel Translation. 2015;45:254–257.
- Gromov VE, Peregudov OA, Ivanov YF, et al. Surface layer structure degradation of rails in prolonged operation. J Surf Inv X-ray Synchr Neutr Technol. 2016;10:76–82.
- Peregudov VE, Gromov YF, Ivanov KV, et al. Physical nature of rail strengthening in long term operation. AIP Conf Proc. 2015;1683:020179.
- Hirsch PB, Howie A, Nicholson RB, et al. Electron microscopy of thin crystals. Melbourne: Krieger Publishing Co.; 1977.
- Utevskii LM: The diffraction electron microscopy in physical metallurgy. Moscow: Metallurgiya; 1973.
- Panin VE, Likhachev VA, Grinyaev Y: Structural levels of deformation of solids. Novosibirsk: Nauka; 1985.
- Eshelby J. The continuum theory of dislocations. Moscow: ILI; 1963.
- Gromov VЕ, Kozlov EV, Bazaikin VI, et al. Physics and mechanics of drawing and die forging. Moscow: Nedra; 1997.