The effect of calcium ions (Ca2+) on the corrosion of API 5L X80 carbon steel in carbon dioxide (CO2)-saturated brines was studied. Tests were performed in brines containing 0 ppm, 1,000 ppm, or 5,000 ppm of calcium ions with a constant chloride ion concentration at temperatures of 35°C and 60°C, and pressure of 80 bar. The corrosion rates were determined by mass loss, and the protective properties of the film were evaluated by performing electrochemical measurements in a separate vessel containing a standard brine. The results showed that adding Ca2+ to the brine slightly reduced the average corrosion rate, even without a crystalline corrosion product scale. For longer exposure times, it promoted the growth of a mixed iron-calcium carbonate (FexCayCO3) scale with increasing calcium molar mass, shifting the scale morphology from prismatic crystals (pure FeCO3) to globular (mixed carbonate). At 35°C the mixed iron-calcium carbonate scale offered better protection when compared to the pure FeCO3 scale counterpart. However, at 60°C, where a thicker carbonate scale was formed, the increased Ca2+ content had a minimal effect on the corrosion rate.

Subject
Scanning electron microscopy, Steel surfaces, Precipitation (solids), Corrosion rate, Mass loss, Carbonate scales, Average corrosion rates, Corrosion products, Corrosion scales, Scale formation, Brines, Carbon steel, Immersion
Keywords:
calcium carbonate, CO2 corrosion, high temperature, iron carbonate, mixed carbonate
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2023
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