| METALS AND METAL MATRIX COMPOSITES |
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| Effect of D-amino Acid Enhanced Bactericide on Corrosion Behavior of Three Metal Materials |
| XU Congmin1,*, LI Xueli1, ZHU Wensheng2, ZHU Shidong1, YANG Xing1, GAO Haoran1, SUN Shuwen1
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1 School of Materials Science and Engineering, Xi’an Shiyou University, Xi’an 710065, China
2 CNOOC Changzhou Paint and Coating Industry Research Institute Co., Ltd., Suzhou 213000, Jiangsu, China |
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Abstract The effects of D-amino acid enhanced compound bactericide on corrosion resistance behavior and mechanism of 45# carbon steel, 316L stainless steel and H62 brass in sulfate reducing bacteria (SRB) + iron oxidizing bacteria (IOB) were studied by biological culture technology, bactericidal process evaluation, weight loss experiment, electrochemical test and surface analysis. The results showed that the corrosion depth of different metals a year without bactericide was as follows, 45# carbon steel (0.104 2 mm/a) >H62 brass (0.045 6 mm/a) > 316L stainless steel (0.007 3 mm/a). Because the SRB and IOB in the mixed bacteria have a synergistic effect to accelerate the corrosion of metal mate-rials. After adding the bactericide, the bactericidal rate of SRB and IOB in the mixed bacteria exceeded 99% and 90%, respectively, the polarization curves of the three metals all shifted to the left, the icorrdecreased in a varying degree, the corrosion rate reduced significantly, and the depth and number of pitting pits decreased significantly. Moreover, the content of P and S in microbial metabolites decreased significantly, it indicated that the number of viable bacteria decreased sharply. With or without bactericide, 316L stainless steel has the best corrosion resistance due to the easy formation of chromium oxide passivation film on the surface, and H62 brass has good corrosion resistance due to Cu2+ bactericidal effect. The tetrakis hydroxymethyl phosphonium sulphate (THPS) in the compound bactericide can change the properties of cellular enzymes and proteins to cause the death of bacteria, meanwhile D-amino acids can decompose the biofilm on the surface of the metal, which can change the bacteria from the hard-to-kill fixed state to the easy-to-kill floating state to improve the bactericidal effect, and also avoid the formation of high concentrations of extracellular polymer EPS, thereby reduce the corrosion rate of the metal.
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Published: 25 October 2024
Online: 2024-11-05
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| Fund:National Natural Science Foundation of China (51974245, 21808182), Shaanxi Provincial Key R & D Program (2020GY-234), Xi’an Key Laboratory of High Performance Oil and Gas Field Materials, School of Materials Science and Engineering, Xi’an Shiyou University, Xi’an Shiyou University ‘Materials Science and Engineering’ Provincial Advantageous Discipline Funding Project (YS37020203), Xi’an Shiyou University Postgraduate Innovation and Practical Ability Training Project (YCS22213138). |
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2024, Vol. 38 
