. Nace-mr0175-/, ISO 15156 Standard, Sulfide stress cracking resistant metallic materials for oilfield equipment, 1998.

E. Remita, B. Tribollet, E. Sutter, V. Vivier, F. Ropital et al., Hydrogen evolution in aqueous solutions containing dissolved CO 2 : Quantitative contribution of the buffering effect, Corrosion Science, vol.50, issue.5, pp.1433-1440, 2008.
URL : https://hal.archives-ouvertes.fr/hal-02419557

J. L. Crolet and G. Maisonneuve, Construction of a universal scale of severity for hydrogen cracking, Corrosion, p.127, 2000.

P. Manolatos, M. Jerome, and J. Galland, Necessity of a palladium coating to ensure hydrogen oxidation during electrochemical permeation measurements on iron, Electrochimica Acta, vol.40, issue.7, pp.867-871, 1995.

P. Manolatos, M. Jerome, C. Duret-thual, and J. Le-coze, The electrochemical permeation of hydrogen in steels without palladium coating. Part I: Interpretation difficulties, Corrosion Science, vol.37, issue.11, pp.1773-1783, 1995.

P. Manolatos and M. Jerome, A thin palladium coating on iron for hydrogen permeation studies, Electrochimica Acta, vol.41, issue.3, pp.359-365, 1996.

J. L. Crolet and M. R. Bonis, Revisiting hydrogen in steel, part I: theoretical aspects of charging, stress cracking and permeation, Corrosion, p.1067, 2001.

S. Duval, R. Antano-lopez, C. Scomparin, M. Jerome, and F. Ropital, Hydrogen permeation through ARMCO iron membranes in sour media, Corrosion, p.4740, 2004.

J. Kittel, F. Ropital, and J. Pellier, Effect of membrane thickness on hydrogen permeation in steels during wet H 2 S exposure, Corrosion, vol.64, issue.10, pp.788-799, 2008.
URL : https://hal.archives-ouvertes.fr/hal-02420852

M. A. Devanathan and Z. Stachurski, The mechanism of hydrogen evolution on iron in acid solutions by determination of permeation rates, Journal of the Electrochemical Society, vol.111, issue.5, pp.619-623, 1964.

B. and L. Boucher, Étude du dégagement cathodique de l'hydrogène sur le fer en présence d'hydrogène sulfuré, 1963.