We study the effect of laser irradiation on the initiation and development of corrosion defects near nonmetallic inclusions in steels. It is established that the procedure of laser treatment improves the corrosion resistance under the conditions of low-cycle fatigue of steels containing various inclusions. It is shown that the effect of laser treatment on the formation of corrosion defects in steels is connected with changes in the state of the inclusion–matrix interfaces, which decreases their permeability for corrosive elements and increases the cohesive strength of these interfaces in active media.
Similar content being viewed by others
References
S. I. Gubenko, Physics of Fracture of Steels Near Nonmetallic Inclusions [in Russian], NMetAU, IC “Sistemnye Tekhnologii”, Dnepropetrovsk (2014).
G. I. Kotel’nikov, D. A. Movenko, K.L. Kosyrev, P. C. Kulish, S. A. Motrenko, and A. V. Stonoga, “Numerical analysis of the corrosion activity of nonmetallic inclusions in pipe steel,” Électrometallurgiya, No. 2, 36–39 (2011).
I. G. Rodionova, O. N. Baklanova, and A. I. Zaitsev, “On the role of nonmetallic inclusions in the acceleration of local corrosion processes in oil-field pipelines made of carbon and low-alloy steels,” Metally, No. 5, 13–18 (2004).
I. G. Rodionova, O. N. Baklanova, and A. I. Zaitsev, “On the problem of composition and properties of corrosion-active nonmetallic inclusions in pipe steels and the mechanisms of their influence on corrosion,” in: Corrosion-Active Nonmetallic Inclusions in Carbon and Low-Alloy Steels [in Russian], Metallurgizdat, Moscow (2005), pp. 15–36.
S. I. Gubenko, A. B. Sychkov, E. V. Parusov, and A. I. Denisenko, “Corrosive damage close to nonmetallic inclusions in bearing steel,” Steel Translat., 48, No. 3, 197–201 (2018).
X. Wang, Q. Lu, W. Zhang, Z. Xie, and C. Shang, “Investigation on the correlation between inclusions and high temperature urea corrosion behavior in ferritic stainless steel,” Metals, No. 11, 1823–1831 (2021).
D. Jia, L. Zhong, J. Yu, Z. Liu, Y. Zhou, C. Tian, and W. Dai, “The effects of morphology of ferrite and nonmetallic inclusions on corrosion behaviour of as-cast 304 stainless steel,” Corrosion, 77, No. 10, 1060–1071 (2021).
Y. Wang, X. Zhang, L. Cheng, J. Liu, T. Hou, and K. Wu, “Correlation between active/inactive (Ca, Mg, Al)-Ox-Sy inclusions and localized marine corrosion of EH36 steel,” J. Mat. Res. Technol., 13, No. 4, 2419–2432 (2021).
S. Tokuda, I. Muto, Y. Sugawara, and N. Hara, “High-temperature heat-treatment at 1673 K: Improvement of pitting corrosion resistance at inclusions of type 304 stainless steel under applied stress,” Mat. Transact., 63, No. 2, 265–268 (2022).
A. B. Kuslitskii, Nonmetallic Inclusions and the Fatigue of Steel [in Russian], Tekhnika, Kiev (1976).
V. I. Likhtman, E. D. Shchukin, and P. A. Rehbinder, Physicochemical Mechanics of Materials [in Russian], Izd. Akad. Nauk SSSR, Moscow (1962).
S. I. Gubenko, “Zones of contact interaction in steel matrix near inclusions under the laser action,” Mater. Sci., 46, No. 4, 448–452 (2011).
Author information
Authors and Affiliations
Corresponding author
Additional information
Translated from Fizyko-Khimichna Mekhanika Materialiv, Vol. 58, No. 3, pp. 33–37, May–June, 2022.
Rights and permissions
Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.
About this article
Cite this article
Gubenko, S.I. Effect of Laser Surface Treatment on the Initiation of Corrosion Defects near Nonmetallic Inclusions. Mater Sci 58, 313–317 (2022). https://doi.org/10.1007/s11003-023-00665-7
Received:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11003-023-00665-7