PSI - Issue 68

Louka Eleftheria-Sotiria et al. / Procedia Structural Integrity 68 (2025) 894–900 Louka Eleftheria-Sotiria et al. / Structural Integrity Procedia 00 (2025) 000–000

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Acknowledgements The work has been financed by the Hellenic Foundation for Research and Innovation H.F.R.I.-Project ID 03385 Acronym CorLi-Corrosion susceptibility, degradation and protection of advanced Al-Li aluminium alloys. References ASTM International, 2009. Standard Test Methods for Tension Testing of Metallic Materials. ASTM E8M. West Conshohocken, PA. Alexopoulos, N. D., Charalampidou, C. M., Skarvelis, P., & Kourkoulis, S. K., 2017. Synergy of corrosion-induced micro-cracking and hydrogen embrittlement on the structural integrity of aluminium alloy (Al-Cu-Mg) 2024. Corros. Sci., pp. 32–42. Alexopoulos, N. D., Siskou, N., Charalampidou, C., & Kourkoulis, S., 2019. Simulation of the corrosion-induced damage on aluminum alloy 2024 specimens with equivalent surface notches. Frat. ed Integr. Strutt., pp. 342–353. Alexopoulos, N. D., Velonaki, Z., Stergiou, C. I., & Kourkoulis, S. K., 2016. The effect of artificial ageing heat treatments on the corrosion induced hydrogen embrittlement of 2024 (Al–Cu) aluminium alloy. Corros. Sci., pp. 413–424. Alexopoulos, N., Proiou, A., Dietzel, W., Blawert, C., Heitmann, V., Zheludkevich, M., & Kourkoulis, S., 2016. Mechanical properties degradation of (Al-Cu-Li) 2198 alloy due to corrosion exposure. Procedia Struct. Integr., pp. 597–603. Alexopoulos, N., Proiou, A., Examilioti, T., Kashaev, N., Riekehr, S., & Kourkoulis, S., 2016. Effect of artificial aging on the mechanical performance of (Al-Cu) 2024 and (Al- Cu-Li) 2198 aluminum alloys. Proc. Struct. Integr., pp. 3782–3783. ASTM International, 2001. Standard Test Method for Exfoliation Corrosion Susceptibility in 2XXX and 7XXX Series Aluminum Alloys (EXCO Test). ASTM G34. West Conshohocken, PA. Charalampidou, C., Dietzel, W., Zheludkevich, M., Kourkoulis, S., & Alexopoulos, N., 2021. Corrosion-induced mechanical properties degradation of Al-Cu-Li (2198-T351) aluminium alloy and the role of side-surface cracks. Corros. Sci., 109330. Dursun, T., & Soutis, C., 2014. Recent developments in advanced aircraft aluminium alloys. Mater. Des., pp. 862–871. Ma, Y., Zhou, X., Liao, Y., Yi, Y., Wu, H., Wang, Z., & Huang, W., 2015. Localised corrosion in AA2099-T83 aluminium-lithium alloy: the role of grain orientation. Corros. Sci., pp. 41–48. Moreto, J. A., Gamboni, O. C., Marino, C. E., Filho, W. B., Fernandes, J. C., & Rocha, L. A., 2012. Corrosion behaviour of Al and Al-Li alloys used as aircraft materials. Corros. Prot., pp. 60–64. Prasad, N., Gokhale, A., & Rao, P., 2003. Mechanical behaviour of aluminium-lithium alloy. Sadhana, pp. 209–246. Rioja, R. J., & Liu, J., 2012. The evolution of Al-Li base products for aerospace and space applications. Metall. Mater. Trans. A, pp. 3325–3337. Zhang, X., Zhou, X., Hashimoto, T., Lindsay, J., Ciuca, O., Luo, C., Tang, Z., 2017. The influence of grain structure on the corrosion behaviour of 2A97-T3 Al- Cu-Li alloy. Corros. Sci., pp. 14–21.