High entropy alloy (HEA) is a new generation material composed of multiple elements in equal proportions. To investigate the corrosion properties of HEA, FeCrNiCoMn and FeCrNiCo alloys were chosen in this study, focusing on whether Mn element can have an influence on corrosion resistance. Simultaneously, 304L stainless steel would become the control group in all of the experiments. The results showed that no passive region was exhibited in the FeCrNiCoMn polarization curve, and pitting occurred at a much lower potential compared to previous studies, on the other hand, FeCrNiCo exhibited a wide passive region in the polarization curve. In 304L stainless steel, the passive region could be exhibited in the polarization curve, and pitting potential was obviously higher than that of FeCrNiCoMn even though both of them had nearly the same concentration of Cr. By SEM and EDX analysis, a substantial number of inclusions composed of sulfide and oxide existed in the FeCrNiCoMn and FeCrNiCo specimens. Moreover, many research have reported that MnS dissolution might inhibit the passivation behavior around the inclusion. By XPS analysis, the results showed that a high percentage of Mn and Cr oxides were contained in the passive film, so it was reasonable to presume that Mn competes with Cr in the oxidation reaction so that Cr_2 O_3 decrease in the passive film and leads to a much lower pitting potential. To eliminate the harmful MnS inclusion, surface treatments including Multiple Pickling-Passivation (MP-P) and Nitric Acid Pickling-Passivation (NP-P) were carried out; the former effectively removed most of the sulfide and oxide, but the latter could solely remove sulfide. Besides, the superior corrosion resistance in the electrochemical test might result from Cr_2 O_3 enrichment in the passive film by surface treatments, but under the negative effect of fluoride ion, MP-P had less improvement in corrosion resistance compared to NP-P. In the final chapter, SEM and EDX Mapping were used to analyze the specimens which were polarized to pitting potential, confirming that MnS was the pitting initiation site for both FeCrNiCoMn and 304L stainless steel. Owing to remove most of the initiation sites of pitting, pitting numbers dropped largely after performing surface treatments.