Effects of the chromium-depleted, mill-finished surface on the localized corrosion resistance of alloy 825 (UNS N08825) were investigated. Tests were conducted in solutions based on the ground water at Yucca Mountain, Nevada, but with a higher concentration of chloride (Cl). Results indicated that breakdown (Ep) and repassivation (Erp) potentials for mill-finished surfaces were more active than those for polished surfaces. Potentiodynamic polarization tests indicated pits could be initiated on the chromium-depleted surface at potentials of 220 mVSCE in a solution containing 1,000 ppm Cl at 95°C. Potentiostatic tests identified a similar pit initiation potential for the mill-finished surface. However, under long-term potentiostatic tests, a higher potential of 300 mVSCE was needed to sustain stable pit growth beyond the chromium-depleted layer. An increase in surface roughness also was observed to decrease localized corrosion resistance of the material.

Subject
Surface finishing, Pits, Materials, Composition, Metal surfaces, Chromium, Corrosion initiation, Potentiostatic scans, Surface layers, Electric potential, Pitting, Localized corrosion, Alloys
Keywords:
alloy 825, chloride, chromium depletion, corrosion resistance, ground water, localized corrosion, nuclear waste, pitting, radioactive waste containers
NACE International
1995
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