Electrochemical study on hot corrosion of Si-modified aluminide coated In-738LC in Na2SO4-20 wt.% NaCl melt at 750°C

The corrosion performance of the slurry Si-modified alummide coating on the nickel base superalloy In-738LC exposed to low temperature hot corrosion condition has been investigated in Na2SO4-20 wt.% NaCl melt at 750 degreesC by combined use of the anodic polarization and characterization techniques. The coated specimen showed a passive behavior up to -0.460 V vs. Ag/AgCl (0.1 mol fraction) reference electrode, followed by a rapid increase in anodic current due to localized attack in the higher potential region. In the passive region, the anodic dissolution of constituents of the coating occurred through the passive film, probably SiO2, at slow rate of 20-30 mutA/cm(2). The passive current for the Si-modified coating was two orders of magnitude smaller than that for bare In-738LC, which is known as Cr2O3 former in this melt. This indicates that the SiO2 film is chemically more stable than Cr2O3 film under this condition. However, pitting-like corrosion commenced around -0.460 V and proceeded at the high rate of 100 mA/cm(2) in the higher potential region than +0.400 V. The corrosion products formed on the coating polarized in different anodic potentials were characterized by SEM, EDS and XRD. It was found from the characterization that oxidation was dominant attack mode and no considerable sulfidation occurred at 750 degreesC. The SiO2 oxide was not characterized in the passive region because the thickness of the passive film was extremely thin, but was detected as the primary oxide in the localized corrosion region, where the selective oxidation of Al was observed by further progress of the corrosion attack front into the inner layer of coating. (C) 2002 Elsevier Science Ltd. All rights reserved.