Influence of ferrous iron on the rate and nature of microbiologically influenced corrosion of high-strength steel under sulfate-reducing conditions

The influence of ferrous iron, sulfate reduction, and stress were examined in the microbiologically influenced corrosion (MIC) of mild steel by Desulfovibrio desulfuricans subsp. aestuarii (American Type Culture Collection [ATCC] 29578). Corrosion was measured by monitoring the electrical resistance...

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Bibliographic Details
Published in:Corrosion (Houston, Tex.) Tex.), 2005-11, Vol.61 (11), p.1070-1077
Main Authors: ROYER, R. A, UNZ, R. F
Format: Article
Language:English
Subjects:
American Type Culture Collection
Applied sciences
Bacterial corrosion
Biological effects
Corrosion
Corrosion environments
Corrosion mechanisms
Corrosion rate
Corrosion resistance
Corrosion resistant steels
Corrosion tests
Cracking (corrosion)
Dissolution
Dissolving
Electrical resistance
Electrical resistivity
Electrochemistry
Electrode polarization
Exact sciences and technology
High strength steels
Incubation period
Iron
Levels
Low carbon steels
Metals. Metallurgy
Minimum inhibitory concentration
Penetration resistance
Steel
Steel wire
Stress corrosion
Stress corrosion cracking
Sulfate reduction
Sulfate resistance
Sulfates
Sulfide
Sulfides
Sulphate reduction
Sulphides
Tensile stress
Uniform attack (corrosion)
Wire
Wire ropes
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Summary:The influence of ferrous iron, sulfate reduction, and stress were examined in the microbiologically influenced corrosion (MIC) of mild steel by Desulfovibrio desulfuricans subsp. aestuarii (American Type Culture Collection [ATCC] 29578). Corrosion was measured by monitoring the electrical resistance of a thin steel wire used as an electrical resistance probe (ERP) over time. Measurable corrosion required active sulfate reduction and ferrous iron concentrations of 1.2 mM or greater. Corrosion occurring at the highest Fe(II) levels tested (12 mM and 18 mM Fe[II]) was characterized by a marked increase in resistance that was readily explained by the electrochemical dissolution of the wire. Corrosion at lower iron levels resulted in a more rapid failure of the ERP (severance of electrical continuity) but less electrochemical dissolution (as determined by resistance increase). Increasing ferrous iron levels, therefore, appeared to result in a transition from a highly localized rapid attack to a more uniform attack with a lower maximum rate of penetration. Average corrosion rates, based upon resistance, were found to increase during incubation in all cases where a resistance increase was detectable. Similar patterns were observed with rates derived from potentiodynamic polarization. Corrosion at the lowest Fe(II) level (1.2 mM), which consistently produced failure of the wires, appeared to occur through a mechanism involving both sulfide and tensile stress. Continued sulfate reduction was required at the low iron level to produce rapid failure of the wire samples, indicating that sulfate reduction not only initiated the observed corrosion but also was important in sustaining it. Elevated sulfide levels at low Fe(II) levels may have resulted in biologically induced sulfide stress corrosion cracking (SSCC). The results of this study emphasize the importance of sulfate reduction in initiating and sustaining aggressive MIC. In addition, an unexpected relationship was observed between the rate and uniformity of corrosion as a function of the ferrous iron concentration.
ISSN:0010-9312
1938-159X
DOI:10.5006/1.3280623