PSI - Issue 59

Jesús Toribio et al. / Procedia Structural Integrity 59 (2024) 145–150 Jesús Toribio / Procedia Structural Integrity 00 ( 2024) 000 – 000

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Toribio, J., Ayaso, FJ., 2004. Optimisation of Round-Notched Specimen for Hydrogen Embrittlement Testing of Materials. Journal of Materials Science Letters 39, 4675-4678. Toribio, J., Elices, M., 1992. The Role of Local Strain Rate in the Hydrogen Embrittlement of Round-Notched Samples. Corrosion Science 33, 1387-1395. Toribio, J., Lancha, AM., Elices, M., 1991. Macroscopic Variables Governing the Microscopic Fracture of Pearlitic Steels. Materials Science and Engineering A145, 167-177. Toribio, J., Vasseur, E., 1997. Hydrogen-Assisted Micro-Damage Evolution in Pearlitic Steel. Journal of Materials Science Letters 16, 1345-1348. Van Leeuwen, HP., 1974. The Kinetics of Hydrogen Embrittlement: A Quantitative Diffusion Model. Engineering Fracture Mechanics 6, 141-161. Wagenblast, H., Wriedt, HA., 1971. Dilation of Alpha Iron by Dissolved Hydrogen at 450º to 800ºC. Metallurgical Transactions 2, 1393 -1397. Wang, M., Akiyama, E., Tsuzaki, K., 2005a. Crosshead Speed Dependence of the Notch Tensile Strength of a High Strength Steel in the Presence of Hydrogen. Scripta Materialia 53, 713-718. Wang, M., Akiyama, E., Tsuzaki, K., 2005b. Effect of Hydrogen and Stress Concentration on the Notch Tensile Strength of AISI 4135 Steel. Materials Science and Engineering A398, 37-46. Wang, M., Akiyama, E., Tsuzaki, K., 2007. Effect of Hydrogen on the Fracture Behavior of High Strength Steel During Slow Strain Rate Test. Corrosion Science 49, 4081-4097.