Low carbon steel was coated by hot-dipping into a molten bath containing pure Al, Al-7wt%Si, Al-10wt%Si, respectively. Oxidation was studied at 750 and 850℃ in static aft. After hot-dip treatment, it was shown that addition of Si in the molten Al bath was responsible for the formation of a thinner intermetallic layer and smoother interface between the aluminide layer and the steel substrate. The thickness of intermetallic layer was decreased from 50 to 15µm. All the coating layers consisted of three phases, where Al, FeAl3, Fe2Al5 were detected from the external topcoat to the aluminide/steel substrate. After high temperature exposure, a continuous alumina scale was detected on the surface of the aluminide layer. The thickness of the aluminide layer was about 90 and 70µm in each temperature test for Al and Al-Si specimens, respectively, while voids resulting from the Kirkendall effect formed at the interface between the aluminide layer and the steel substrate. The additions of Si into the coating layer were effective to restrained the transformation speed of FeAl2 and Fe2Al5 to FeAl. The oxidation kinetics followed a parabolic rate law at 750℃ for all kinds of coating specimens, while the weight gain of the hot-dip aluminizing coating on the surface of carbon steel is only 1/10 that of the carbon steel under the same oxidation condition. HDAl-10Si specimen has relativity higher oxidation rate for up to about 56 h. Due to the brittleness of the Al-Si aluminized coatings on the carbon steel severe cracking and internal oxidation occurred.