共 89 条
- [1] Baranov V.P., Sergeev N.N., Kinetika razrusheniya i prognozirovanie dolgovechnosti vysokoprochnykh stalei v vodorodosoderzhashchikh sredakh, Tula: Tul’sk. Gos. Pedagog. Univ. Im. L.N. Tolstogo, (2007)
- [2] Izvol'Skii V.V., Sergeev N.N., Korrozionnoe rastreskivanie i vodorodnoe okhrupchivanie armaturnykh stalei zhelezobetona povyshennoi i vysokoi prochnosti, (2001)
- [3] Kolachev B.A., Hydrogen Embrittlement of Metals, (1985)
- [4] Dayal R.K., Parvathavarthini N., Hydrogen embrittlement in power plant steels, Sadhana, 28, pp. 431-451, (2003)
- [5] Sergeev N.N., Chukanov A.N., Baranov V.P., Yakovenko A.A., Development of damage and decarburization of high-strength low-alloy steels under hydrogen embrittlement, Met. Sci. Heat Treat., 57, pp. 63-68, (2015)
- [6] Denisov E.A., Kompaniets T.N., Murzinova M.A., Yukhimchuk A.A., Accumulation and transport of hydrogen in RUSFER-EK-181 ferritic-martensitic steel, Tech. Phys., 58, pp. 814-820, (2013)
- [7] Sergeev N.N., Kutepov S.N., Gvozdev A.E., Ageev E.V., Mechanisms of hydrogen cracking of metals and alloys related to increase of dislocation activity, Izv. Yugo-Zap. Gos. Univ., 22, 2, pp. 34-52, (2017)
- [8] Beachem C.D., New model for hydrogen assisted cracking (hydrogen embrittlement), Metall. Trans., 3, pp. 437-451, (1972)
- [9] Hirth J.P., Effects of hydrogen on the properties of iron and steel, Metall. Trans. A, 11, pp. 861-890, (1980)
- [10] Zapffe C.A., Sims C.E., Hydrogen embrittlement, internal stress and defects in steel, Trans. AIME, 145, pp. 225-261, (1941)