The electrochemical corrosion behavior of three Fe-Cr alloys (containing SB45O, STP A24, and STP A26) after hot corrosion with 2mg/cm^2 NaC1/Na2SO4 deposits at 750℃ and 850℃ were studied in 3.5% NaC1 aqueous electrolyte. The corrosion mechanism was evaluated in terms of scale morphology by OM and SEM, XRD, and dynamic polarization curve measurements. The results showed that the higher Cr content in alloy the lower i(subscript corr) and the higher E (subscript corr) poetntial which tends to be more noble. The lowest i(subscript corr) and a passivation characteristics, STP A26 displayed the best corrosion resistance of the three alloys. Because the oxy-chlorination took place when hot corrosion with the NaC1 deposits, scales become more porous and easy to corrode, leading to an increase of i(subscript corr) by a factor of 2 as compared to the raw materials. Thus, the reproduction of cyclic polarization curve gets worse, and the E (subscript corr) decreased. On the other hand, the scales are more dense in simple oxidation, so that crevice corrosion is more difficult to occur. As a result, icorr will be close to that of the raw material, and the reproduction of cyclic polarization curve is second to raw materials, however the corrosion resistance is highly improved. As increasing temperature and exposure duration, the dominating hot-corrosion environment change to simple oxidation in air or Na2SO4-deposit. The overall reaction is favorable to form dense oxide scales, which reduces the i(subscript corr) but increases the E (subscript corr). However, the high-defective Fe(subscript 1-x)O scale retained on the alloy cause a significant increase in the i(subscript corr)r as compare to the specimen without Fe(subscript 1-x)O.