PSI - Issue 28

Alla V. Balueva et al. / Procedia Structural Integrity 28 (2020) 873–885 Author name / Structural Integrity Procedia 00 (2019) 000–000

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Results demonstrate the intriguing fact that even real gas pressures do not begin with a constant rate of growth, but, as time approaches infinity, growth rate begins to become constant, and further, at the same rate as the ideal gas case. This fact will prompt us to look for an analytical relationship between the ideal and real gas models. Acknowledgements The research was done with partial support of RFBR grants No. 17-08-01579 and No. 17-08-01312 and of contract #AAAA-A17-117021310386-3. Authors are thankful to UNG student Christian Schneider for help with preparation Addach, H., Bercot, P., Rezrazi, M., and Wery, M. (2005). Hydrogen Permeability in Iron at Different Temperatures. Materials Letters, 59(11) , 1347 – 1351. Balueva A.V., and Goldstein, R.V. (1992). Kinetic Crack Propagation in a Layer, with Gas Diffusion, Mechanics of Solids , 2 , 114-123. Balueva, A.V. and Dashevskiy, I.N. (1994). Model of Internal Gas-filled Crack Growth in Materials . Mechanics of Solids. 6, 113-118. Balueva, A.V. and Dashevskiy, I.N. (1999). The Growth of Hydrogen Delaminations in Metals . Mechanics of Solids, 1, 119-123. Balueva, A.V. (2008). Asymptotical Approach to the Constant Velocity of Hydrogen Delamination Growth, Int. J. of Mech. Sci ., Vol. 50, p. 22-29. Balueva, A.V. and Germanovich, L.N. (2012). Asymptotical Analysis and Pade Approximation in Problems on Diffusion-Controlled Cracks Propagation. Revista de Mathematica: Theory and Applications , 19(2) , 127–139. Balueva, A.V. and Dashevskiy, I.N. (2016). “Modeling of the Gas - Controlled Crack Growth: Non-Ideal vs. Ideal Sink.” Proceedings of the ASME International Mechanical Engineering Congress and Exposition ASME2016 , November 11 - 17 2016, Phoenix Arizona, USA. Beggs, D.V., and Hahn, M.T. (1984). Recent Observation on the Propagation of Stress Corrosion Cracks and Their Relevance to Proposed Mechanisms of Stress Corrosion Cracking, In: Hydrogen Embrittlement and Stress Corrosion Cracking , Edited by Gibala, R. and Hehemann, R.F., American Society for Metals, Metal Park, Ohio 44073, 181-205. Benbelaid, S., Belouchrani, M.A., Assoul, Y., Bezzazi, B. (2011). Modeling Damage of the Hydrogen Enhanced Localized Plasticity in Stress Corrosion Cracking. International Journal of Damage Mechanics 20. 831-844. Claeys, l., Cnockaert, V., Depover, T., De Graeve, I., Verbeken, K. (2020). Critical assessment of the evaluation of thermal desorption spectroscopy data for duplex stainless steels: A combined experimental and numerical approach. Acta Materialia , 186 , 190-198. Cui, T.C., Liu, P.F., Gu, C.H. (2017). Finite element analysis of hydrogen diffusion/plasticity coupled behaviors of low-alloy ferritic steel at large strain. Internation Journal of Hydrogen Energy , 42, 20324-20335. Eliaz, N., Banks-Sills, L., Ashkenazi, D., and Eliasi, R. (2004). Modeling Failure of Metallic Glasses due to Hydrogen Embrittlement in the Absence of External Loads. Acta Materialia, 52 , 93 – 105. Garabedian, P.R. (1986). Partial Differential Equations , AMS Chelsea Publishing, Providence, Rhode Island, 672 pp. Goldstein R.V., Entov V.M., and Pavlovsky B.R. (1977). Model of Development of Hydrogen Cracks in Metal, Academiia nauk SSSR. Doklady . 237 , 4 , 828-831. Jothi, S., Croft, T.N., Brown, S.G.R. (2014). Multiscale multiphysics model for hydrogen embrittlement in polycrystalline nickle. Journal of Alloys and Compounds 645. 5500-5504. Laureys, A., Depover, T., Petrov, R., Verbeken, K. (2015). Microstructural characterization of hydrogen induced cracking in TRIP-assisted steel by EBSD. Materials Characterization 112. 169-179. Masoumi, M., Silva C.C., Béreš, M., Ladion D.H., Gomes de Abreu, H.F. (2016). Role of crystallographic texture on the improvement of hydrogen-induced crack resistance in API 5L X70 pipeline steel. International Journal of Hydrogen Energy 42. 1318-1326. Nagao, A., Mohsen D., Somerday, B. P., Sofronis, P., Ritchie, R.O. (2018). Hydrogen-enhanced-plasticity mediated decohesion for hydrogen induced intergranular and “quasi-cleavage” fracture of lath materialistic steels. Journal of the Mechanics and Physics of Solids 112. 403-430. Nykyforchyn, H.M. and Student, O.Z. (2006). Assessment of High-Temperature Hydrogen Degradation of Power Equipment Steels. Proceedings of the 16 th European Conference of Fracture on CD , Alexandroupolis, Greece. Oriani RA. (1970). The diffusion and trapping of hydrogen in steel. Acta Metallurgica . 18(1):147-157. Sofronis, P., Robertson, I.M., Johnson, D.D., Somerday, B. (2007). Hydrogen Embrittlement: Fundamentals, Modeling and Experiment. Presented at: DOE Hydrogen Pipeline Working Group Meeting. of the paper. References