Rapid α-AlO Growth on an Iron Aluminide Coating at 600 °C in the Presence of O, HO, and KCl.

In this work, a slurry iron aluminide-coated ferritic steel SVM12 was subjected to a laboratory experiment mimicking superheater corrosion in a biomass-fired power boiler. The samples were exposed under model Cl-rich biomass conditions, in a KCl + O + HO environment at 600 °C for 168, 2000, and 8000 h. The morphology of corrosion and the composition of the oxide scale and the coating were investigated by a combination of advanced analytical techniques such as FESEM/EDS, SEM/EBSD, and XRD. Even after short-term exposure, the coating developed a very fast-growing and up to 50 μm thick α-AlO scale in contrast to the spontaneous formation of a protective, thin, dense, slow-growing, and very adhesive α-AlO layer usually formed on metallic materials after high-temperature oxidation. In view of the literature on the formation of oxide scales on alloys and coatings, the formation of an α-AlO scale at this relatively low temperature is very surprising in itself. The thick alumina scale was not protective as its formation resulted in fast degradation of the coating and rapid FeAl → FeAl phase transformation, which in turn generated porosity inside the coating. In all cases, the resulting thick AlO scale was porous and consisted of both equiaxed α-AlO grains and randomly oriented aggregated alumina whiskers. Potassium is concentrated in the outer part of the AlO scale, while chlorine is concentrated close to the scale/aluminide interface. The unexpected formation of rapidly growing α-AlO at relatively low temperature is attributed to the hydrolysis of aluminum chloride generated in the corrosion process.