PSI - Issue 2_A

Haiyang Yu et al. / Procedia Structural Integrity 2 (2016) 565–572 H. Yu, JS. Olsen, J.He, Z. Zhang / Structural Integrity Procedia 00 (2016) 000–000

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References Alvaro, A., Thue Jensen, I., Kheradmand, N., Løvvik, O.M., Olden, V., 2015. Hydrogen embrittlement in nickel, visited by first principles modeling, cohesive zone simulation and nanomechanical testing. International Journal of Hydrogen Energy 40, 16892–16900. Bechtle, S., Kumar, M., Somerday, B.P., Launey, M.E., Ritchie, R.O., 2009. Grain-boundary engineering markedly reduces susceptibility to intergranular hydrogen embrittlement in metallic materials. Acta Materialia 57, 4148–4157. Cheung, C., Erb, U., Palumbo, G., 1994. Application of grain boundary engineering concepts to alleviate intergranular cracking in alloys 600 and 690. Materials Science and Engineering: A 185, 39–43. Jothi, S., Croft, T.N., Brown, S.G.R., de Souza Neto, E.A., 2014. Finite element microstructural homogenization techniques and intergranular, intragranular microstructural effects on effective diffusion coefficient of heterogeneous polycrystalline composite media. Composite Structures 108, 555–564. Kobayashi, S., Maruyama, T., Tsurekawa, S., Watanabe, T., 2012. Grain boundary engineering based on fractal analysis for control of segregation-induced intergranular brittle fracture in polycrystalline nickel. Acta Materialia 60, 6200–6212. Lehockey, E.M., Palumbo, G., 1997. On the creep behaviour of grain boundary engineered nickel 1. Materials Science and Engineering: A 237, 168–172. Li, S., Zhou, J., Ma, L., Xu, N., Zhu, R., He, X., 2009. Continuum level simulation on the deformation behavior of nanocrystalline nickel. Computational Materials Science 45, 390–397. Morel, S., Dourado, N., 2011. Size effect in quasibrittle failure: Analytical model and numerical simulations using cohesive zone model. International Journal of Solids and Structures 48, 1403–1412. Needleman, A., 1990. An analysis of decohesion along an imperfect interface. International Journal of Fracture 42, 21–40. Needleman, A., 2014. Some issues in cohesive surface modeling. Procedia IUTAM 10, 221–246. Olden, V., Thaulow, C., Johnsen, R., Østby, E., Berstad, T., 2008. Application of hydrogen influenced cohesive laws in the prediction of hydrogen induced stress cracking in 25steel. Engineering Fracture Mechanics 75, 2333–2351. Oriani, R.A., 1972. A mechanistic theory of hydrogen embrittlement of steels. Berichte der Bunsengesellschaft für physikalische Chemie 76, 848–857. Oudriss, A., Creus, J., Bouhattate, J., Conforto, E., Berziou, C., Savall, C., Feaugas, X., 2012. Grain size and grain-boundary effects on diffusion and trapping of hydrogen in pure nickel. Acta Materialia 60, 6814–6828. Pezzotta, M., Zhang, Z.L., Jensen, M., Grande, T., Einarsrud, M.A., 2008. Cohesive zone modeling of grain boundary microc racking induced by thermal anisotropy in titanium diboride ceramics. Computational Materials Science 43, 440–449. Shimada, M., Kokawa, H., Wang, Z.J., Sato, Y.S., Karibe, I., 2002. Optimization of grain boundary character distribution for intergranular corrosion resistant 304 stainless steel by twin-induced grain boundary engineering. Acta Materialia 50, 2331–2341. Song, J., Curtin, W.A., 2011. A nanoscale mechanism of hydrogen embrittlement in metals. Acta Materialia 59, 1557–1569. Stenerud, G., Johnsen, R., Olsen, J.S., 2015. Susceptibility to hydrogen induced stress cracking of uns n07718 and uns n07725 under cathodic polarization, in: CORROSION 2015, NACE International. Turon, A., Dávila, C.G., Camanho, P.P., Costa, J., 2007. An engineering solution for mesh size effects in the simulation of delamination using cohesive zone models. Engineering Fracture Mechanics 74, 1665–1682. Wei, Y.J., Anand, L., 2004. Grain-boundary sliding and separation in polycrystalline metals: application to nanocrystalline fcc metals. Journal of the Mechanics and Physics of Solids 52, 2587–2616. Yamaguchi, M., Shiga, M., Kaburaki, H., 2006. Grain boundary decohesion by sulfur segregation in ferromagnetic iron and nickel —a first-principles study—. Materials Transactions 47, 2682–2689. Yu, H., Olsen, J.S., Alvaro, A., Olden, V., He, J., Zhang, Z., 2016. A uniform hydrogen degradation law for high strength steels. Engineering Fracture Mechanics 157, 56–71.