Authors: Mandlenkosi George Robert Mahlobo, Peter Apata Olubambi, Philippe Refait

Abstract:

The aim of this study was to use voltammetry as a method to understand the behavior of steel in unsaturated soil in the presence of cathodic protection (CP). Three carbon steel coupons were buried in artificial soil wetted at 65-70% of saturation for 37 days. All three coupons were left at open circuit potential (OCP) for the first seven days in the unsaturated soil before CP which was only applied on two of the three coupons at the protection potential -0.8 V vs. Cu/CuSO4 for the remaining 30 days of the experiment. Voltammetry was performed weekly on the coupon without CP while electrochemical impedance spectroscopy (EIS) was performed daily to monitor and correct the applied CP potential from ohmic drop. Voltammetry was finally performed the last day on the coupons under CP. All the voltammograms were modeled with mathematical equations in order to compute the electrochemical parameters and subsequently deduce the corrosion rate of the steel coupons. For the coupon without CP, the corrosion rate was determined at 300 µm/y. For the coupons under CP, the residual corrosion rate under CP was estimated at 12 µm/y while the corrosion rate of the coupons, after interruption of CP, was estimated at 25 µm/y. This showed that CP was efficient due to two effects: a direct effect, from the decreased potential, and an induced effect, associated with the increased interfacial pH that promoted the formation of a protective layer on the steel surface.

Keywords: Carbon steel, cathodic protection, voltammetry, unsaturated soil, Raman spectroscopy.

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References:

[1] William, S.F. and Javad, H. (2006), Foundations of Materials Science and Engineering (4th ed.), McGraw-Hill, ISBN 0-07-295358- 6
[2] Ismail, A.I.M. and El-Shamy, A.M. (2009). "Engineering behavior of soil materials on the corrosion of mild steel." Applied Clay Science 42: 356-362.
[3] Yan, M., Sun, C., Xu, J., Dong, J. and Ke, W. (2014). "Role of Fe oxides in corrosion of pipeline steel in a red clay soil." Corrosion Science 80: 309-317.
[4] Kodym, R., Snita, D., Fíla, V., Bouzek, K. and Kouri, M. (2017a). "Investigation of processes occurring at cathodically protected underground installations: Experimental study of pH alteration and mathematical modeling of oxygen transport in soil." Corrosion Science 120: 14-27.
[5] Kodym, R., Snita, D., Fíla, V., Bouzek, K. and Kouril, M. (2017b). "Investigation of processes occurring at cathodically protected underground installations: Mathematical modeling of reaction-transport processes in soil." Corrosion Science 120: 28-41.
[6] Cole, I.S. and Marney, D. (2012). "The science of pipe corrosion: A review of the literature on the corrosion of ferrous metals in soils." Corrosion Science 56: 5-16.
[7] Akkouche, R., Rémazeilles, C., Jeannin, M., Barbalat, M., Sabot, R. and Refait, Ph. (2016). "Influence of soil moisture on the corrosion processes of carbon steel in artificial soil: Active area and differential aeration cells." Electrochimica Acta 213: 698-708.
[8] Nguyen, D.D., Lanarde, L., Jeannin, M., Sabot, R. and Refait, Ph. (2015). "Influence of soil moisture on the residual corrosion rates of buried carbon steel structures under cathodic protection." Electrochimica Acta 176: 1410-1419.
[9] Barbalat, M., Lanarde, L., Caron, D., Meyer, M., Vittonato, J., Castillon, F., Fontaine, S. and Refait, Ph. (2012). "Electrochemical determination of residual corrosion rates of steel under cathodic protection in soils." Corrosion Science 55: 246-253.
[10] Barbalat, M., Caron, D., Lanarde, L., Meyer, M., Fontaine, S., Castillon, F., Vittonato, J. and Refait, Ph. (2013). "Estimation of residual corrosion rates of steel under cathodic protection in soils via voltammetry." Corrosion Science 73: 222-229.
[11] Akkouche, R., Rémazeilles, C., Barbalat, M., Sabot, R., Jeannin, M. and Refait, Ph. (2017). "Electrochemical monitoring of steel/soil interfaces during wet/dry cycles." Journal of Electrochemical Society 164(12): 626-634.
[12] Rahal, C., Masmoudi, M., Abdelhedi, R., Sabot, R., Jeannin, M., Bouaziz, M. and Refait, Ph. (2016). “Olive leaf extract as a natural corrosion inhibitor for pure copper in 0.5M NaCl solution: A study by voltammetry around OCP” Journal of Electroanalytical Chemistry 769: 53-61.
[13] Gupta, S.K. and Gupta, B.K. (1979). “The critical soil moisture content in the underground corrosion of mild steel” Corrosion Science 19. 171-178.
[14] Neale, C.N., Hughes, J.B. and Ward, C.H. (2000). “Impacts of unsaturated zone properties on oxygen transport and aquifer reaeration” Ground Water 38. 784–794.
[15] Leeds, S.S. and Cottis, R.A. (2006). “An investigation into the influence of surface films on the mechanism of cathodic protection”, CORROSION/2006, paper No. 06084, National Association of Corrosion Engineers, Houston, Texas.
[16] De Faria, D.L.A., Silva, S.V. and Oliveira, M.T.D. (1997). “Raman micro spectroscopy study of some iron oxides and oxyhydroxides” J. Raman Spectroscopy. 28. 873–878.
[17] Tomic, Z. Makreski, P. and Gajic, B. (2010). “Identification and spectra–structure determination of soil minerals: Raman study supported by IR spectroscopy and X-ray powder diffraction” J. Raman Spectroscopy. 41. 582-586.