ACTIVE/PASSIVE BEHAVIOR OF LOW CARBON STEEL IN DEAERATED BICARBONATE SOLUTION

doi:10.3724/SP.J.1037.2013.00497

Acta Metall Sin

2014, Vol. 50

Issue (3): 275-284 DOI: 10.3724/SP.J.1037.2013.00497

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ACTIVE/PASSIVE BEHAVIOR OF LOW CARBON STEEL IN DEAERATED BICARBONATE SOLUTION

WEN Huailiang^1,², DONG Junhua²(

), KE Wei², CHEN Wenjuan², YANG Jingfeng², CHEN Nan²

1 College of Chemical and Materials Science, University of Science and Technology of China, Hefei 230026
2 State Key Laboratory for Corrosion and Protection, Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016

Cite this article:

WEN Huailiang, DONG Junhua, KE Wei, CHEN Wenjuan, YANG Jingfeng, CHEN Nan. ACTIVE/PASSIVE BEHAVIOR OF LOW CARBON STEEL IN DEAERATED BICARBONATE SOLUTION. Acta Metall Sin, 2014, 50(3): 275-284.

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Abstract

As a kind of clean, efficient and relatively safe energy, nuclear energy has been widely used around the world. The high-level radioactive waste (HLRW) generated in the nuclear has also become a major risk, so the disposal safety of HLRW will be especially important. The planned concept of China's HLRW disposal program is a shaft-tunnel model located in saturated zones in granite. The metal container for sealing the HLRW is the key because its interaction with the ground water will lead to the leak of the HLRW during the long repository time. Beishan is a selected repository area and the ground water contains a bicarbonate ( $H C O 3 -$ ) buffer solution. Therefore, as a candidate material of the container, the active/passive state of low carbon steel in the ground water with is of significance, which determines the container's service life. The active state will ensure that the container achieves the designed life under general corrosion, and moreover the passive state will degrade the container's life under stress corrosion cracking (SCC) caused by pitting corrosion. In this work, the effect of $H C O 3 -$ on the corrosion behavior of low carbon steel was examined in deaerated bicarbonate solutions (pH 8.3) over 50 d. The presence of $H C O 3 -$ enhanced both the anodic Fe dissolution and cathodic hydrogen evolution reaction. The situ-measurement of corrosion potential revealed that the increased concentration of $H C O 3 -$ led to the high corrosion potential. When the concentration of $H C O 3 -$ was 0.01 mol/L, the corrosion potential was in the active region. When the concentration of $H C O 3 -$ was higher than 0.02 mol/L, the corrosion potential was in the passive region. EIS results showed that the charge transfer resistance, film resistance and the diffusion impedance increased with the increasing $H C O 3 -$ concentration. Results of XRD analysis illustrated that the key corrosion products were mainly composed of Fe₃O₄ and α-FeOOH.

Key words: low carbon steel passive/active high-level radioactive waste disposal H C O 3 - ')" href="#">

H C O 3 -

deaeration corrosion

Received: 18 August 2013

ZTFLH:

TF777.1

Fund: Supported by National Natural Science Foundation of China (No.51071160)

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	Huailiang WEN
	Junhua DONG
	Wei KE
	Wenjuan CHEN
	Jingfeng YANG
	Nan CHEN

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https://www.ams.org.cn/EN/10.3724/SP.J.1037.2013.00497 OR https://www.ams.org.cn/EN/Y2014/V50/I3/275

Figure 1. Polarization curves of low carbon steel in 0.01 mol/L(a), 0.02 mol/L (b), 0.05 mol/L (c) and 0.1 mol/L (d)deaerated

H C O 3 -

solutions

Figure 2. Evolution of open circuit potential in 0.01 mol/L(a), 0.02 mol/L (b), 0.05 mol/L (c) and 0.1 mol/L (d)deaerated

H C O 3 -

solutions

Figure 3. Measured EIS results of low carbon steel in 0.01 mol/L

H C O 3 -

deaerated solutions (ZIm—imaginative part of electrochemical impedance, ZRe—real part of electrochemical impedance, f—frequency, Z—impedance)

(a) ZIm-ZRe (b) Z-f (c) phase angle-f

Figure 4. Measured EIS results of low carbon steel in 0.02 mol/L

H C O 3 -

deaerated solutions

(a) ZIm-ZRe (b) Z-f (c) phase angle-f

Figure 5. Measured EIS results of low carbon steel in 0.05 mol/L

H C O 3 -

deaerated solutions (Inset in Fig.5a shows the enlarged view)

(a) ZIm-ZRe (b) Z-f (c) phase angle-f

Figure 6. Measured EIS results of low carbon steel in 0.1 mol/L

H C O 3 -

deaerated solutions

(a) ZIm-ZRe (b) Z-f (c) phase angle-f

Figure 7. Equivalent circuit for fitting the EIS data (Q_p—capacitance caused by high frequency phse shift, R_s—solution resistance, Q_r—rust capacitance, R_r—real part of electrochemical impedance, Q_dl—double layer capacitance, R_ct—charge transfer resistance, W—Warburg impedance)

Table 1 Fitting results for EIS plots in 0.01 mol/L

H C O 3 -

solution

Table 2 Fitting results for EIS plots in 0.02 mol/L

H C O 3 -

solution

Table 3 Fitting results for EIS plots in 0.05 mol/L

H C O 3 -

solution

Table 4 Fitting results for EIS plots in 0.1 mol/L

H C O 3 -

solution

[1]	Wang J, Su R, Chen W M, Guo Y H, Jin Y X, Wen Z J, Liu Y M. Chin J Rock Mech Eng, 2006; 25: 649
	(王驹, 苏锐, 陈伟明, 郭永海, 金远新, 温志坚, 刘月妙. 岩石力学与工程学报, 2006; 25: 649)
[2]	Gordon G M. Corrosion, 2002; 58: 811
[3]	King F, Padovani C. Corros Eng Sci Technol, 2011; 46: 82
[4]	Saheb M, Neff D, Dillmann P, Matthiesen H, Foy E. J Nucl Mater, 2008; 379: 118
[5]	Yang J F, Dong J H, Ke W. Acta Metall Sin, 2011; 47: 1321
	(阳靖峰, 董俊华, 柯伟. 金属学报, 2011; 47: 1321)
[6]	Taniguchi N, Honda A, Ishikawa H. MRS Symp Process, 1998; 506: 495
[7]	Thomas J G N, Nurse T J, Walker R. Br Corros J, 1970; 5(2): 87
[8]	Armstrong R D, Coates A C. J Electroanal Chem, 1974; 50: 303
[9]	Castro E B, Valentine C R, Monia C A, Vilche J R, Arvia A J. Corros Sci, 1986; 26: 781
[10]	Castro E B, Vilche J R, Arvia A J. Corros Sci, 1991; 32: 37
[11]	Rozenfeld J L. Atmospheric Corrosion of Metals. Houston: NACE, 1972: 1
[12]	Féron D, Crusset D, Gras J M. J Nucl Mater, 2008; 379: 16
[13]	Videm K, Dugstad A. Mater Perform, 1989; 28(4): 46
[14]	Davies D H, Burstein G T. Corrosion, 1980; 36: 416
[15]	Valentini C R, Moina C A, Vilche J R, Arvia A J. Corros Sci, 1985; 25: 985
[16]	Wersin P, Spahin K, Bruno J. SKB Technical Report (9402). Stockholm: Swedish Nuclear Fuel and Waste Management Co., 1994: 1
[17]	Smart N R, Blackwood D J, Werme L. Corrosion, 2002; 58: 547
[18]	Smart N R, Blackwood D J, Werme L. Corrosion, 2002; 58: 627
[19]	Reardon E J. Environ Sci Technol, 1995; 29: 2936
[20]	Dong J H, Nishimura T, Kodama T. MRS Symp Process, 2002; 713: 105
[21]	Nishimura T, Dong J H. J Power Energy System, 2009; 3: 23
[22]	Azoulay I, Rémazeilles C, Refait P. Corros Sci, 2012; 58: 229
[23]	Marsh G P, Taylor K J, Bland I D, Westcott C, Tasker P W, Sharland S M. MRS Symp Process, 1985; 50: 421
[24]	Hao L, Zhang S X, Dong J H, Ke W. Corros Sci, 2012; 59: 270
[25]	Cox B, Wong Y M. J Nucl Mater, 1995; 218: 324
[26]	Orazem M E, Tribollet B. Electrochemical Impedance Spectroscopy. New York: John Wiley & Sons, 2008: 246
[27]	Cao C N,Zhang J Q. Introduction of Electrochemical Impedance Spectroscopy. Beijing: Science Press, 2002: 88
	(曹楚南,张鉴清. 电化学阻抗谱导论. 北京: 科学出版社, 2002: 88)
[28]	Almeida E, Morcillo M, Rosales B M, Marrocos M. Mater Corros, 2000; 51: 859
[29]	Yamashita M, Miyuki H, Nagaro H, Misawa T. Corros Sci, 1994; 36: 283

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