Page 164 - Дисертаця Венгринюк
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164
58. Liu Q., Atrens A. D., Shi Z. et al. Determination of the hydrogen fugacity
during electrolytic charging of steel. Corrosion Science. 2014. Vol. 87. P. 239–258.
59. Chen Y.-S., Huang C., Liu P.-Y. et al. Hydrogen trapping and
embrittlement in metals – A review. International Journal of Hydrogen Energy.
2025. Vol. 136. Р. 789–821.
60. Barrera O., Bombac D., Chen Y. et al. Understanding and mitigating
hydrogen embrittlement of steels: a review of experimental, modelling and design
progress from atomistic to continuum. Journal of Materials Science. 2018. Vol. 53.
P. 6251–6290.
61. Duncan A., Lam P. S., Adams T. Tensile testing of carbon steel in high
pressure hydrogen. American Society of Mechanical Engineers, Pressure Vessels
and Piping Division. (Publ.) PVP 2008. Vol. 6. Р. 519–525.
62. Moro I., Briottet L., Lemoine P. et al. Hydrogen embrittlement
susceptibility of a high strength steel X80. Materials Science and Engineering. 2010.
Vol. 527. Р. 7252–7260.
63. Nanninga N. E., Levy Y. S., Drexler E. S. et al. Comparison of hydrogen
embrittlement in three pipeline steels in high pressure gaseous hydrogen
environments. Corrososion Science. 2012. Vol. 59. P. 1–9.
64. Marchi C. S., Somerday B. P . Technical Reference for Hydrogen
Compatibility of Materials. Sandia National Laboratories (SNL): Albuquerque, NM,
USA, 2012.
65. Hejazi D., Calka A., Dunne D., Pereloma E. Effect of gaseous hydrogen
charging on the tensile properties of standard and medium Mn X70 pipeline steels.
Materials Science and Technology. 2016. Vol. 32. P. 675–683.
66. Paterlini L., Re G., Curia A. et al. Mechanical Testing Methods for
Assessing Hydrogen Embrittlement in Pipeline Steels: A Review. Metals. 2025.
Vol. 15, No. 10. Article No. 1123.
67. Li T., Zhang H., Hu W. et al. Hydrogen Embrittlement Behavior and
Applicability of X52 Steel in Pure Hydrogen Pipelines. Materials. 2025. Vol. 18,
No 14. Article No. 3417.

