METALS AND METAL MATRIX COMPOSITES |
|
|
|
|
|
Microelectrode Array Technology Used for Investigating the Corrosion of Alloys |
BU Hongmei1, LI Xiaowei2, QI Jiantao3, LI Yan1
|
1 College of Materials Science and Engineering, China University of Petroleum (East China), Qingdao 266580 2 China Petroleum Engineering Construction Corp., Beijing Company, Beijing 100000 3 College of Chemical Engineering, China University of Petroleum (East China), Qingdao 266580 |
|
|
Abstract With the booming development and improvement of the industries, the employment of alloy materials also increases. However, the corrosion problem of alloy materials has caused incalculable losses to industrial production and ecological environment. In order to reduce the da-mage and impact of various aspects caused by alloy corrosion, domestic and foreign scholars have carried out a large number of researches on alloy corrosion mechanism and protection, and some research progress has been made. Microelectrode array technology is a new type of electrochemical test method between macroscopic classical electrochemical technology and micro-area scanning probe technology. It can not only obtain the overall average information of the large-area electrode of the alloy, but also detect the characteristics of potential and current distribution in the local micro-area of the alloy. Compared with the macroscopic classical electrochemical technology, it can more accurately test the heterogeneous electrochemical information in the local corrosion process of the alloy. The optimization of such microelectrode arrays has been realized with the continuous research and development of scholars at home and abroad. By the combination of other electrochemical testing techniques and surface science and technology methods, the physical, chemical and electrochemical information of the alloy/corrosion solution interface has been enriched. In recent years, a great deal of experts and scholars have used this microelectrode array technology combined with other testing techniques to study the local corrosion process and mechanism of common alloys under diffe-rent environments and corrosion conditions, and achieved important research progress. The research on the galvanic corrosion behavior and evolution law of different material metals has made a major breakthrough. In addition, the development and application of real-time coupled multi-electrode array sensor (CMAS) probes play an important role in online monitoring/detection of local corrosion of alloys. In this paper, we reviewed the progress of microelectrode array technology in the study of galvanic corrosion, surface coating failure and the influence of corrosion environment on alloy. Then we summarized the merits and demerits of microelectrode array technology in characterizing the local electrochemical heterogeneity of the alloy and the future trend was prospected.
|
Published: 30 September 2019
|
|
Fund:This work was financially supported by the Fundamental Research Funds for the Central Universities (18CX02128A), and the National Natural Science Foundation of China (51701239). |
About author:: Hongmei Bu received her B.E. degree from the College of Materials Science and Engineering, China University of Petroleum (East China) in 2017. She is currently pursuing her master’s degree at Materials Science and Engineering, China University of Petroleum (East China) under the supervision of Prof. Yan Li and associate professor Jiantao Qi. Her research was funded by the NSFC project of “Multiscale Characterization and Controllable Preparation of Functional Conversion Coatings on Magnesium Alloys”. Jiantao Qi received his bachelor degree in the College of Chemical Engineering, China University of Petroleum (CUP, East China) in 2011 and the doctoral degree from Corrosion and Protection Centre, School of Mate-rials, University of Manchester in 2015. He has rich engineering and research experience as an independent postdoc researcher, competing the LATEST 2 project with Prof. George Thompson (OBE, RAE Fellow) at University of Manchester and the NEPAL FUI project in the PCS lab (ENSCP-CNRS) with cooperation of Prof. Philippe Marcus. He started as a lecture in the CUP at June 2016 and was promoted to be a full associate professor and supervisor of master students at Dec. 2017. His research focuses on corrosion and protection of alloys, including surface modification, functional conversion coatings, physics and chemistry at the surface and interface, SERS Raman, XPS, RBS, electrochemical assessments and corrosion protection strategy. |
|
|
1 |
Baker H. ASM handbook: Alloy phase diagrams, ASM International, America,1992.2 Cao C N. Introduction to electrochemical impedance spectroscopy, Science Press, China,2002(in Chinese).曹楚南.电化学阻抗谱导论,科学出版社,2002.3 Gao Z M, Song S Z. Journal of Chinese Society for Corrosion and Protection,2008,28(4),193(in Chinese).高志明,宋诗哲.中国腐蚀与防护学报,2008,28(4),193.4 Wang L W, Li X G, Du C W, et al. Chinese Journal of Corrosion and Protection,2010,30(6),498(in Chinese).王力伟,李晓刚,杜翠薇,等.中国腐蚀与防护学报,2010,30(6),498.5 Fan W J, Zhao X D, Xing S H, et al. Hot Working Process,2015,44(22),15(in Chinese).樊伟杰,赵晓栋,邢少华,等.热加工工艺,2015,44(22),15.6 Huang G L, Xue M L, Zi Y Z. World Nonferrous Metals,2018(6),217(in Chinese).黄国亮,薛蔓凌,字映竹.世界有色金属,2018(6),217.7 Lin C J, Li Y, Lin B, et al. Electrochemistry,2009,15(2),121(in Chinese).林昌健,李彦,林斌,等.电化学,2009,15(2),121.8 Ji D W. Study on monitoring technology of pipeline inner wall corrosion. Ph.D. Thesis, Dalian University of Technology, China,2010(in Chinese).纪大伟.管道内壁腐蚀监测技术研究.博士学位论文,大连理工大学,2010.9 Zhang H Y. Study on internal corrosion law of sour gas gathering pipeline. Master’s Thesis, China University of Petroleum (East China), China,2013(in Chinese).张宏阳.含酸气集输管道的内腐蚀规律研究.硕士学位论文,中国石油大学(华东),2013.10 Fan L, Xing Q, Qiu R, et al. Corrosion Science and Protection Technology,2015,27(5),509(in Chinese).范林,邢青,邱日,等.腐蚀科学与防护技术,2015,27(5),509.11 General Administration of Quality Supervision, Inspection and Quarantine of the People’s Republic of China. GB150. Pressure vessels, first part: General requirements,2011(in Chinese).中华人民共和国国家质量监督检验检疫总局.GB150.压力容器,第1部分:通用要求,2011.12 Maurice V, Marcus P. Progress in Materials Science,2018,95,132.13 Yang R, Li Y. Corrosion Science and Protection Technology,2014,26(3),259(in Chinese).杨瑞,李焰.腐蚀科学与防护技术,2014,26(3),259.14 Zhong Q D. Chinese Journal of Corrosion and Protection,1999,19(3),189(in Chinese).钟庆东.中国腐蚀与防护学报,1999,19(3),189.15 Li G P. Effect of stress on intergranular corrosion of 2024 aluminum alloy. Master’s Thesis, Shenyang University, China,2018(in Chinese).李贵鹏.应力对2024铝合金晶间腐蚀的影响.硕士学位论文,沈阳大学,2018.16 Huang Z. Anticorrosion structure and material application of car body. Master’s Thesis, Wuhan University of Technology, China,2009(in Chinese).黄湛.轿车车身防腐结构及材料应用.硕士学位论文,武汉理工大学,2009.17 Xie F. Corrosion and Protection of Petrochemical Industry,2004,21(3),56(in Chinese).谢凤.石油化工腐蚀与防护,2004,21(3),56.18 Xie F. Corrosion and Protection of Petrochemical Industry,2004,21(4),1(in Chinese).谢凤.石油化工腐蚀与防护,2004,21(4),1.19 Qiang M S, Jiang J H, Song D, et al. Corrosion and Protection,2015,36(7),677(in Chinese).强明闪,江静华,宋丹,等.腐蚀与防护,2015,36(7),677.20 Yu H. Corrosion behavior of cast Mg-Li-Al-Ca alloy in NaCl solution. Master’s Thesis, Jilin University, China,2012(in Chinese).于泓.铸造态Mg-Li-Al-Ca合金在NaCl溶液中的腐蚀行为研究.硕士学位论文,吉林大学,2012.21 Yuan B. Study on corrosion of AZ31 magnesium alloy surface treated with 45 steel. Master’s Thesis, Xi’an University of Technology, China,2006(in Chinese).袁兵.表面处理AZ31镁合金与45钢连接腐蚀的研究.硕士学位论文,西安理工大学,2006.22 Krebs H M. The microstructure and corrosion performance of AZ31B-H24 magnesium alloy sheet. Ph.D. Thesis, The University of Manchester, United Kingdom,2017.23 Wu P P. Study on corrosion resistance of Mg-Al-Ca alloy. Master’s Thesis, Taiyuan University of Technology, China,2018(in Chinese).武鹏鹏.Mg-Al-Ca合金耐腐蚀性能研究.硕士学位论文,太原理工大学,2018.24 Zeng R, Dietzel W, Zettler R, et al. Transactions of Nonferrous Metals Society of China,2014,24(10),3060.25 Weng Y J, Zhao H Y. Chinese Journal of Corrosion and Protection,2003,23(6),7(in Chinese).翁永基,赵海燕.中国腐蚀与防护学报,2003,23(6),7.26 Tan Y J. Material Protection,1993,26(8),17(in Chinese).谭勇军.材料保护,1993,26(8),17.27 Lin C J, Zhuo X D, Chen J D, et al. Chinese Journal of Corrosion and Protection,1997,17(01),9(in Chinese).林昌健,卓向东,陈纪东,等.中国腐蚀与防护学报,1997,17(01),9.28 Zhong Q D, Shu Y D, Jiang H Y. Chinese Journal of Corrosion and Protection,1997,17(4),43(in Chinese).钟庆东,舒余德,蒋汉瀛.中国腐蚀与防护学报,1997,17(4),43.29 Eren H, M. Lowe A, Tan Y J, et al. IEEE Transactions on Instrumentation and Measurement,1998,47(5),1096.30 Wang W, Zhang X, Wang J. Electrochimica Acta,2009,54(23),5598.31 李焰,刘玉,张大磊.中国专利,ZL201220622726.5,2012.32 Ding L. Electrochemical behavior and mechanism of TA2/HAl77-2/316L SS corrosion zone in seawater desalination plant. Master’s Thesis, China University of Petroleum (East China), China,2016(in Chinese).丁莉.海水淡化装置中TA2/HAl77-2/316L SS腐蚀体系微区电化学行为和机理研究.硕士学位论文,中国石油大学(华东),2016.33 Zhang D L, Wang W, Li Y. Journal of Materials Research,2009,23(4),343(in Chinese).张大磊,王伟,李焰.材料研究学报,2009,23(4),343.34 Zhang D L, Wang W, Jin Y H, et al. Chinese Journal of Nonferrous Me-tals,2011,21(9),2168(in Chinese).张大磊,王伟,金有海,等.中国有色金属学报,2011,21(9),2168.35 Cao K L, Cheng C Q, Zhao J. Material Protection,2016,49(7),27(in Chinese).曹快乐,程从前,赵杰.材料保护,2016,49(7),27.36 Cao K L. Study on non-uniformity of galvanic corrosion of brass and stainless steel by tow electrode. Master’s Thesis, Dalian University of Technology, China,2016(in Chinese).曹快乐.丝束电极研究黄铜/不锈钢电偶腐蚀的非均匀性.硕士学位论文,大连理工大学,2016.37 Yang R. Corrosion electrochemical behavior of X80 pipeline steel in NACE solution. Master’s Thesis, China University of Petroleum (East China), China,2015(in Chinese).杨瑞.X80管线钢在NACE溶液中的腐蚀电化学行为研究.硕士学位论文,中国石油大学(华东),2015.38 Liu H J. Study on galvanic corrosion of marine steel under organic coating. Master’s Thesis, Ocean University of China, China,2011(in Chinese).刘华剑.有机涂层下船用钢电偶腐蚀规律研究.硕士学位论文,中国海洋大学,2011.39 Zhang G, Yu N, Yang L, et al. Corrosion Science,2014,86,202.40 Guo H, Cheng X D, Zhang H X, et al. Journal of Electroplating and Fi-nishing,2018,40(6),17(in Chinese).郭晗,程旭东,张慧霞,等.电镀与精饰,2018,40(6),17.41 Ju H, Duan J, Yang Y, et al. Materials,2018,11(4),634.42 Tan Y J. Progress in Organic Coatings,1991,19(1),89.43 Tan Y J, Shiti Y. Progress in Organic Coatings,1991,19(1),257.44 Kong D Y. Study on degradation process of organic coatings by combined tow electrode technique and electrochemical impedance spectroscopy. Master’s Thesis, Ocean University of China, China,2011(in Chinese).孔德艳.联合丝束电极技术和电化学阻抗技术研究有机涂层劣化过程.硕士学位论文,中国海洋大学,2011.45 Tan Y. Corrosion Science,1998,41(2),229.46 Tan Y, Bailey S, Kinsella B. Corrosion Science,2001,43(10),1931.47 Tan Y, Aung N N, Liu T. Corrosion Science,2012,63,379.48 Tan Y. Corrosion Science,2005,47(7),1653.49 Changjian L. Electrochemistry (Chinese),1996,2(2),144.50 Zhang W, Wang J, Li Y N, et al. Journal of Physical Chemistry,2010,26(11),2941(in Chinese).张伟,王佳,李玉楠,等.物理化学学报,2010,26(11),2941.51 Thu Q L, Bonnet G, Compere C, et al. Progress in Organic Coatings,2005,52(2),118.52 Liu Q B, Deng P C, Hu J Z, et al. Guangzhou Chemical Industry,2016,44(18),19(in Chinese).刘泉兵,邓培昌,胡杰珍,等.广州化工,2016,44(18),19.53 Liu J, Liu H F, Xu L M, et al. Corrosion and Protection,2001,22(8),325(in Chinese).刘靖,刘宏芳,许立铭,等.腐蚀与防护,2001,22(8),325.54 Wang W, Wang J. In:2012 Academic Annual Meeting-China Corrosion Electrochemistry and Test Methods Committee. Chengdu,2012,pp.4(in Chinese).王伟,王佳.中国腐蚀电化学及测试方法专业委员会2012学术年会.成都,2012,pp.4.55 Dong Z H, Shi W, Ruan H M, et al. Corrosion Science,2011,53(9),2978.56 Zhang X, Wang W, Wang J. Corrosion Science and Protection Technology,2009,21(3),242(in Chinese).张霞,王伟,王佳.腐蚀科学与防护技术,2009,21(3),242.57 Aung N N, Tan Y J. Corrosion Science,2004,46(12),3057.58 Dong Z H, Shi W, Guo X P. Journal of Physical Chemistry,2011,27(1),127(in Chinese).董泽华,石维,郭兴蓬.物理化学学报,2011,27(1),127.59 Yu N, Xu B H, Zhang G A, et al. In: The 17th National Corrosion Inhibitor Academic Discussion and Application Technology Experience Exchange Meeting.Chongqing,2012,pp.7(in Chinese).喻能,许炳辉,张国安,等.第十七届全国缓蚀剂学术讨论及应用技术经验交流会.重庆,2012,pp.7.60 Zeng L. Scouring corrosion mechanism and fluid dynamics of pipe elbow. Ph.D. Thesis, Huazhong University of Science and Technology, China,2017(in Chinese).曾莉.管道弯管段冲刷腐蚀机理与流体动力学特征.博士学位论文,华中科技大学,2017.61 Zhao W H, Cai G Y, Dong Z H. In:National Academic Conference on Corrosion Electrochemistry and Test Methods in 2016. Qingdao,2016,pp.2(in Chinese).赵苇杭,蔡光义,董泽华.2016年全国腐蚀电化学及测试方法学术交流会.青岛,2016,pp.2.62 Chen Y L, Zhang W, Wang W, et al. Chinese Journal of Corrosion and Protection,2014,34(5),451(in Chinese).陈亚林,张伟,王伟,等.中国腐蚀与防护学报,2014,34(5),451.63 Zhang X. Study on the mechanism of waterline corrosion using array electrodes. Master’s Thesis, Ocean University of China, China,2013(in Chinese).张雪.利用阵列电极研究水线腐蚀的机理.硕士学位论文,中国海洋大学,2013.64 Zhang J L, Hou B R, Guo G Y, et al. Ocean and Lake,1995,26(1),98(in Chinese).张经磊,侯保荣,郭公玉,等.海洋与湖沼,1995,26(1),98.65 Hu J Z, Li X G, Deng P C, et al. Corrosion Science and Protection Technology,2015,27(6),551(in Chinese).胡杰珍,李晓刚,邓培昌,等.腐蚀科学与防护技术,2015,27(6),551.66 Su J X, Liu B, Guo Y. Corrosion and Protection,2018,39(2),129(in Chinese).苏景新,刘波,郭英.腐蚀与防护,2018,39(2),129.67 Shi W, Dong Z H, Kong D J, et al. Cement and Concrete Research,2013,48,25.68 Kenneth Chiang K, Yang L. Recent Patents on Computer Science,2011,1(1),108.69 Yang L, Sridhar N. In: CORROSION 2006.2006,pp.06681.70 Chen J S, Yang D, Fu D Y, et al. Journal of Materials and Metallurgy,2008,7(3),233(in Chinese).陈建设,杨栋,付东宇,等.材料与冶金学报,2008,7(3),233.71 Yang L, Dunn D. In: CORROSION 2002. Colorado, 2002, pp.02004.
|
|
|
|