ICF13B

13th International Conference on Fracture June 16–21, 2013, Beijing, China -10- [11] T. Sakai, H. Kaji, Nucleation and growth of bubbles formed by hydrogen attack in carbon and low alloy steels. Tetsu-to-Hagané, 64 (1978) 430-438. [12] S. Nomura, M. Hasegawa, Effect of cementite distribution in low carbon steel on hydrogen attack. Tetsu-to-Hagané, 61 (1975) 2579-2588. [13] J. Ovejero-García, Hydrogen microprint technique in the study of hydrogen in steels. Journal of Materials Science, 20 (1985) 2623-2629. [14] K. Ichitani, M. Kanno, Visualization of hydrogen diffusion in steels by high sensitivity hydrogen microprint technique. Science and Technology of Advanced Materials, 4 (2003) 545-551. [15] H. Matsunaga, H. Noda, Visualization of hydrogen diffusion in a hydrogen-enhanced fatigue crack growth in type 304 stainless steel. Metallurgical and Materials Transactions A, 42 (2011) 2696-2705. [16] A. Demarez, A.G. Hocks, Meuniers FA. Diffusion of hydrogen in mild steel. Acta Metallurgica, 2 (1954) 214-223. [17] C.D. Beachem, A new model for hydrogen-assisted cracking (hydrogen “embrittlement”). Metallurgical and Materials Transactions B, 3 (1972) 441-455. [18] H.K. Birnbaum, P. Sofronis, Hydrogen-enhanced Localized Plasticity ― A Mechanism for Hydrogen-related Fracture. Materials Science and Engineering: A, 176 (1994) 191-202.

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