Mechanochemically sulfidated microscale zero valent iron (S-mZVI^bm) is a promising groundwater remediation material as it has been proven to be not only efficient in dechlorinating chlorinated compounds but also amenable to up-scaling. Yet, its efficiency in treating metal contaminants remains barely studied. In this study, we investigated the mechanism and efficiencies of Cr(VI) removal by S-mZVI^bm and its effect on TCE dechlorination as a co-contaminant. The Cr(VI) removal by S-mZVI^bm was mainly a chemisorption process and its kinetics was well fitted by a pseudo-second-order model. Alkaline pH inhibited Cr(VI) removal while dissolved oxygen slightly depressed the Cr(VI) removal. The Cr(VI) removal rapidly formed a non-conductive layer on S-mZVI^bm surface to hinder further electron transfer from Fe⁰ core before H⁺ was able to accept any electrons to produce H₂, which resulted in 100% electron efficiencies of Cr(VI) removal but <1% of Fe⁰ utilization efficiency. The presence of Cr(VI) also dramatically inhibited the dechlorination of TCE and its electron efficiency as a co-contaminant by passivating the FeS surface. Therefore, Cr(VI) is likely to be an electron sink if present for remediation of other contaminants in groundwater.