Pit Growth Study in Al Alloys by the Foil Penetration Technique

The foil penetration technique was used to study pit growth in AA1100-O and AA2024-T3. Preliminary work on AA1100-O foils of different thicknesses indicated that the pit growth rate increased with increasing applied potential, suggesting that pit growth was not under transport control. Foil penetration experiments were also carried out on AA2024-T3 foils of a given thickness, at open circuit as well as anodic potentials. Dichromate ions and other oxidizing agents were added to some test solutions. Dichromate ions were shown to have little influence on the pit growth rate at controlled anodic potentials, even when added in large concentrations. However, dichromate ions effectively inhibited pitting at open circuit when present in very small amounts. Polarization curves of AA2024-T3 in 1 M NaCl with various additives show a large effect of dichromate ions in the cathodic region and no effect in the anodic region. These observations suggest that chromate (or its reduction product) acts as a cathodic inhibitor. Examination of penetrated samples was performed by optical and scanning electron microscopies, as well as by microradiography.This work was supported by Major H. DeLong at the Air Force Office of Scientific Research, under contract F49620-96-0042

Microradiographic Characterization of Pitting Corrosion Damage and Fatigue Life

Due to the increasing number of aging aircraft, the inspection and assessment of corrosion and fatigue damage on airframe structures is of major concern [1]. Among the different types of corrosion damage, pitting corrosion is an important factor in triggering widespread fatigue crack initiation and reduced fatigue life. Therefore, the ability to predict surface crack origination from pitting corrosion is necessary for timely maintenance of aging aircraft.</p

Pit Growth Study in Al Alloys by the Foil Penetration Technique

The foil penetration technique was used to study pit growth in AA1100-O and AA2024-T3. Preliminary work on AA1100-O foils of different thicknesses indicated that the pit growth rate increased with increasing applied potential, suggesting that pit growth was not under transport control. Foil penetration experiments were also carried out on AA2024-T3 foils of a given thickness, at open circuit as well as anodic potentials. Dichromate ions and other oxidizing agents were added to some test solutions. Dichromate ions were shown to have little influence on the pit growth rate at controlled anodic potentials, even when added in large concentrations. However, dichromate ions effectively inhibited pitting at open circuit when present in very small amounts. Polarization curves of AA2024-T3 in 1 M NaCl with various additives show a large effect of dichromate ions in the cathodic region and no effect in the anodic region. These observations suggest that chromate (or its reduction product) acts as a cathodic inhibitor. Examination of penetrated samples was performed by optical and scanning electron microscopies, as well as by microradiography.This work was supported by Major H. DeLong at the Air Force Office of Scientific Research, under contract F49620-96-0042