Effect of Compound Bactericidal Corrosion Inhibitor on Corrosion Behavior of N80 Steel at Different Temperatures

doi:10.11901/1005.3093.2023.602

Chinese Journal of Materials Research

2025, Vol. 39

Issue (2): 145-152 DOI: 10.11901/1005.3093.2023.602

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Effect of Compound Bactericidal Corrosion Inhibitor on Corrosion Behavior of N80 Steel at Different Temperatures

XU Congmin¹(

), LI Xueli¹, FU Anqing², SUN Shuwen¹, CHEN Zhiqiang¹, LI Chengchen¹

1 School of Materials Science and Engineering, Xi'an Shiyou University, Xi'an 710065, China
2 State Key Laboratory for Performancce and Structure Safety of Petroleum Tubular Goods and Equipment Materials, CNPC Tubular Goods Research Institute, Xi'an 710077, China

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XU Congmin, LI Xueli, FU Anqing, SUN Shuwen, CHEN Zhiqiang, LI Chengchen. Effect of Compound Bactericidal Corrosion Inhibitor on Corrosion Behavior of N80 Steel at Different Temperatures. Chinese Journal of Materials Research, 2025, 39(2): 145-152.

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Abstract

The effect of sulfate-reducing bacteria (SRB) on the corrosion behavior of N80 steel in SRB containing solution at 20, 37 and 50 ^oC, and for this case the effectiveness of a compound bactericidal corrosion inhibitor in the bactericidal effect and corrosion inhibition performance of N80 steel were comparatively investigated via biological culture technique, weightlessness measurement electrochemical testing, and surface analysis etc. The results showed that the corrosion rate of N80 steel was proportional to the SRB activity at different temperatures. The SRB activity was the highest at 37 ^oC, the polarization resistance R_p of N80 steel was the smallest, and the corrosion rate (0.03553 mm/a) was the largest, which was 1.53 times of that at 20 ^oC and 1.16 times of that at 50 ^oC, thus the corrosion was the most serious. However, after adding the compoundbactericidal corrosion inhibitor, the R_p value of N80 steel at 20 and 37 ^oC were increased significantly, and the corrosion of the steel was effectively inhibitedwith corrosion inhibitionefficiency of 65.45% and 64.79%, respectively. This is mainly due to that the lipophilic group hydroxymethyl of the bactericide tetrahydroxymethyl phosphate sulfate (THPS), as one of the components of the compound bactericide corrosion inhibitor, enters the bacterial cell membrane, changes its protein properties, then resulting in bacteria death; Meanwhile the dimethyl sulfoxide promotes the hydroxymethyl of THPS to enter the bacterial cell membrane and enhances the bactericidal effect. As a signal molecule, D-tyrosine, a bactericidal enhancer, promotes the decomposition of biofilm, destroys the surrounding concentration difference, thus slows down the corrosion. The Chitosan in the corrosion inhibitor combined with Fe²⁺ to produce a protective film to protect the substrate, thereby, reducing the corrosion rate. However, at 50 ^oC, the corrosion inhibition efficiency for N80 steel was only 0.26%, which is due to that the excessive temperature intensifies the movement of corrosion inhibitor molecular, increase in the molecular desorption rate adsorbed on the surface of N80 steel and the dissociates the adsorption film, resulting in a very low corrosion inhibition efficiency.

Key words: metallic materials sulfate-reducing bacteria (SRB) compound bactericidal corrosion inhibitor biofilm corrosion behavior

Received: 25 December 2023

ZTFLH:

TQ 152

Fund: National Natural Science Foundation of China(51974245);National Natural Science Foundation of China(21808182);Shaanxi Province Key R&D Program Projects(2020GY-234);Xi'an Key Laboratory of High Performance Oil and Gas Field Materials, School of Materials Science and Engineering, Xi'an Shiyou University, Corrosion protection and New Materials for Oil and Gas Fields in Key Laboratory of Higher Education in Shaanxi Province, Postgraduate Innovation and Practical Ability Training Program of Xi'an Shiyou University(YCS22213138)

Corresponding Authors: XU Congmin, Tel: 18092078500, E-mail: cmxu@xsyu.edu.cn

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	XU Congmin
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	CHEN Zhiqiang
	LI Chengchen

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https://www.cjmr.org/EN/10.11901/1005.3093.2023.602 OR https://www.cjmr.org/EN/Y2025/V39/I2/145

Fig.1 Bacterial concentration and sulfide content of SRB grown at different temperatures for 14 d

Table 1 Bactericidal rate of SRB at different temperature with compound bactericidal corrosion inhibitor

Fig.2 Mass loss and corrosion inhibition rate of N80 steel corroded in SRB solution at different temperatures for 14 d

Table 2 Corrosion inhibition rate of N80 steel at different temperatures with compound bactericidal corrosion inhibitor

Fig.3 N80 corrodes 14 d EIS of (a) Nyquist plots, (b, c) Bode plots in SRB solutions at different tem-peratures

Table 3 EIS fitting results of 14 d corrosion of N80 in SRB solution at different temperatures

Fig.4 Equivalent circuit model of EIS data fitting

Fig.5 N80 steel corroded R $p - 1$ after 14 d in SRB solution at different temperatures

Fig.6 SEM and EDS images of N80 steel corroded in SRB solution at different temperatures for 14 d (a) no bactericidal at 20 ^oC; (b) no bactericidal at 37 ^oC; (c) no bactericidal at 50 ^oC; (d) with bactericidal at 20 ^oC; (e) with bactericidal at 37 ^oC; (f) with bactericidal at 50 ^oC

Fig.7 XRD pattern and corrosion product content of N80 steel after 14 d corrosion in SRB solution

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