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S. Al-Hassan B. Mishra D.L. Olson M.M. Salama (1998) Corrosion 54 IssueID6 480

H. Asahi T. Kushida M. Kimura H. Fukai S. Okano (1999) Corrosion 55 IssueID7 644

R.A. Higgins (1993) ‘Engineering Metallurgy: Applied Physical Metallurgy’ EditionNumber6 Arnold London

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D.A. Lopez S.N. Simison S.R. de Sanchez (2003) Electrochimica Acta 48 845

G.I.W. Ogundele W.E. White (1986) Corrosion 42 IssueID2 71

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V.A. Alves C.M.A. Brett A. Cavaleiro (2001) J. Appl. Electrochem. 31 65

C.L. Waard Particlede U. Lotz D.E. Milliams (1991) Corrosion 47 IssueID12 976

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C.M. Waard Particlede D.E. Milliams (1975) Corrosion 31 IssueID5 131

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G.R.B. Schmitt (1977) Part 1: Kinetics of the liberation of hydrogen, Werkstoffe und Korrosion 28 816

E.P. DeGarmo J.T. Black R. Kosher (1988) ‘Materials and Processes in Manufacturing’ EditionNumber7 Macmillan New York 7

A.M.B.M. Kermani (2003) Corrosion 59 IssueID8 659

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B. Mishra S. Al-Hassan D.L. Olson M.M. Salama (1997) Corrosion 53 IssueID11 852

A. Dugstad H. Hemmer M. Seiersten (2001) Corrosion 57 IssueID4 369

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InstitutionalAuthorNameNACE Task Group, T-1-3 (1984) ‘Introduction, in CO2 Corrosion in Oil and Gas Production-selected Papers, Abstracts and References’ Vol. 3 NACE Houston, Texas

Y.J. Tan, ‘Electrochemical studies on carbon dioxide corrosion and its inhibition’, Ph.D. Thesis, Curtin University, Perth, Australia (1996).

J.L. Mora-Mendoza S. Turgoose (2002) Corros. Sci. 44 1226

L.L. Shreir R.A. Jarman G.T. Burstein (1994) ‘Corrosion’ Oxford Butterworth-Heinemann

This paper presents a fundamental study of the influence of carbon steel microstructure on the corrosion rate. Subsequently, the corrosion performance of various grades of carbon steels were evaluated in stirred autoclaves under elevated carbon dioxide and temperature conditions. Corrosion and penetration rates were determined via mass loss and optical microscopy, respectively. It was found that the corrosion rate of carbon steel line pipe is influenced by microstructure. More specifically, a relationship between localized corrosion susceptibility and the presence of pearlite bands in the steel microstructure was found. However, no correlation was evident between minor elemental concentrations (i.e., Ni, Cr, Mo) and corrosion resistance. It has been proposed that the corrosion stability of the various microstructures may arise from variations in the distribution of carbon bearing phases within the steel. In the banded ferrite/pearlite structure, the carbon-bearing phase (pearlite) is distributed in layers whereas in the other structures the carbon-bearing phases are much more evenly distributed. This study reports on the corrosion resistance of carbon steels in relation to their chemical and physical properties.

D.A. Lopez W.H. Schreiner S.R. de Sanchez S.N. Simison (2003) Appl. Surf. Sci. 207 69

Clover, D., Kinsella, B., Pejcic, B. et al. The influence of microstructure on the corrosion rate of various carbon steels. J Appl Electrochem 35, 139–149 (2005). https://doi.org/10.1007/s10800-004-6207-7