2007
DOI: 10.1016/j.corsci.2007.04.003
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Role of the reversible electrochemical deprotonation of phosphate species in anaerobic biocorrosion of steels

Abstract: Sulphate reducing bacteria are known to play a major role in anaerobic microbiological influenced corrosion of steels, but mechanisms behind their influence are still source of debates as certain phenomena remain unexplained. Some experiments have shown that hydrogen consumption by SRB or hydrogenase increased the corrosion rate of mild steel. This was observed only in the presence of phosphate species. Here the cathodic behaviour of phosphate species on steel was studied to elucidate the role of phosphate in … Show more

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Cited by 21 publications
(13 citation statements)
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“…Less energy is required to extract the hydrogen atom from the acid molecule than from the water molecule. This catalytic pathway is particularly effective on mild steel [168] and stainless steel [166,167] surfaces. It decreases the overpotential necessary for hydrogen evolution, working around neutral pH, using cathodes made of steel, which can be less expensive than nickel alloys.…”
Section: Cathode Materials and Homogeneous Catalysis Of Hydrogen Evolumentioning
confidence: 99%
“…Less energy is required to extract the hydrogen atom from the acid molecule than from the water molecule. This catalytic pathway is particularly effective on mild steel [168] and stainless steel [166,167] surfaces. It decreases the overpotential necessary for hydrogen evolution, working around neutral pH, using cathodes made of steel, which can be less expensive than nickel alloys.…”
Section: Cathode Materials and Homogeneous Catalysis Of Hydrogen Evolumentioning
confidence: 99%
“…Although the detailed mechanisms by which phosphate species lead to the formation of protective layers and the composition of the deposit obtained in phosphate solutions are still research topics, the main point is to have the right amount of Fe II (compared to Fe III) on the material surface that, in contact with the phosphate in the medium, leads to the formation of a vivianite deposit. This is the case in abiotic conditions when using chelating agent for instance [49]; the vivianite layer deposit also depends on phosphate concentration [50,8], on how the preceding oxide layer forms, which is linked to the experimental conditions (electrode potential [51] and the presence or not of oxygen [47,52]). In biotic conditions, other mechanisms are suggested: oxygen consumption by the biofilm as the driving force to form vivianite [53], acceleration of Fe (III) reduction to Fe (II) in presence of microorganisms (such as Geobacter sulfurreducens [54]).…”
Section: Discussion Of the Mechanismsmentioning
confidence: 99%
“…presents the phosphate species as an efficient homogeneous catalyst for the reduction of proton/water [8]. The cathodic deprotonation of phosphate species (Reaction (4)) is relatively fast on steel surfaces and not strictly limited by the forward electron uptake (as is Eq.…”
Section: Mechanism 1: Catalysis Of Hydrogen Consumption With Involvemmentioning
confidence: 99%
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“…Two mechanisms of hydrogenase action on corrosion have been established [5,6,18]. The first involves a synergetic effect between hydrogenase and phosphates (or weak acids) in presence of a redox mediator [18][19][20]. The second mechanism proposed does not require a redox mediator and hydrogenase catalyses the reduction of protons or water by direct electronic transfer [5,6].…”
Section: Introductionmentioning
confidence: 97%