Research on anti-corrosion property of rare earth inhibitor for X70 steel

Three kinds of rare earth nitrates were adopted to sodium molybdate to get three kinds of LnN-M compounded inhibitors (La(NO3)3+Na2MoOa(LaN-M), Ce(NO3)3+Na2MoOn(CeN-M), Pr(NO3)3+Na2MoO4(PrN-M)). The combination of weight-loss method and the electrochemical test, was used to evaluate and analyze the...

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Bibliographic Details
Published inJournal of rare earths Vol. 31; no. 7; pp. 734 - 740
Main Author 朱艳华 庄稼 于永生 曾宪光
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.07.2013
Subjects
Computational efficiency
Computing time
corrosion inhibition performance
Corrosion inhibitors
Corrosion prevention
Corrosion tests
High strength low alloy steels
Inhibition
inhibition mechanism
LA(NO3)3
LnN-M inhibitor
mass-loss method
Na2MoO4
Rare earth metals
rare earths
Steels
X70 steel
X70钢
协同作用
抑制剂
电化学测试
稀土硝酸盐
耐腐蚀性能
inhibition mechanism
LnN-M inhibitor
X70 steel
mass-loss method
corrosion inhibition performance
rare earths
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Summary:Three kinds of rare earth nitrates were adopted to sodium molybdate to get three kinds of LnN-M compounded inhibitors (La(NO3)3+Na2MoOa(LaN-M), Ce(NO3)3+Na2MoOn(CeN-M), Pr(NO3)3+Na2MoO4(PrN-M)). The combination of weight-loss method and the electrochemical test, was used to evaluate and analyze the corrosion inhibition efficiency of these LnN-M inhibitors to make the research on their corrosion inhibition performance, and the sequential order of their performance was found as follows: CeN-M〉 LaN-M〉PrN-M, among which, the inhibition efficiency of CeN-M for the X70 steel could reach 98.21%. The synergism parameters were calculated by weight-loss method, these computational data indicated that the synergistic effect between rare earth nitrates and sodium molybdate was obvious and significant. Surface morphology, chemical composition and phase components of the precipitation films were tested for discussing the mechanism of LnN-M inhibitors. The outer electronic configuration of the lanthanide was found to have an important influence on the inhibition efficiency. The CeN-M inhibitor was discovered to have the best inhibition effect with the amorphous cerium oxides. The results of this research revealed that the precipitation films formed on the surface of the steel samples had a crucial influence on the inhibition efficiencies after adding LnN-M inhibitors.
Bibliography:11-2788/TF
Three kinds of rare earth nitrates were adopted to sodium molybdate to get three kinds of LnN-M compounded inhibitors (La(NO3)3+Na2MoOa(LaN-M), Ce(NO3)3+Na2MoOn(CeN-M), Pr(NO3)3+Na2MoO4(PrN-M)). The combination of weight-loss method and the electrochemical test, was used to evaluate and analyze the corrosion inhibition efficiency of these LnN-M inhibitors to make the research on their corrosion inhibition performance, and the sequential order of their performance was found as follows: CeN-M〉 LaN-M〉PrN-M, among which, the inhibition efficiency of CeN-M for the X70 steel could reach 98.21%. The synergism parameters were calculated by weight-loss method, these computational data indicated that the synergistic effect between rare earth nitrates and sodium molybdate was obvious and significant. Surface morphology, chemical composition and phase components of the precipitation films were tested for discussing the mechanism of LnN-M inhibitors. The outer electronic configuration of the lanthanide was found to have an important influence on the inhibition efficiency. The CeN-M inhibitor was discovered to have the best inhibition effect with the amorphous cerium oxides. The results of this research revealed that the precipitation films formed on the surface of the steel samples had a crucial influence on the inhibition efficiencies after adding LnN-M inhibitors.
LnN-M inhibitor; corrosion inhibition performance; X70 steel; mass-loss method; inhibition mechanism; rare earths
ZHU Yanhua , ZHUANG Jia , YU Yongsheng , ZENG Xianguang (1. School of Materials Science and Engineering, Southwest Petroleum University, Chengdu 610500, China; 2. Material Corrosion and Protection Key Laboratory of Sichuan Province, Zigong 643000, China)
ObjectType-Article-2
SourceType-Scholarly Journals-1
ObjectType-Feature-1
content type line 23
ISSN:1002-0721
2509-4963
DOI:10.1016/S1002-0721(12)60350-0