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We used ab initio molecular dynamics simulations to address Mn oxidation states in different Mn systems. We first develop a correlation between Mn partial atomic charge and the oxidation state, based on results of 31 simulations on known Mn aqueous complexes. The results collapse to a master curve; the dependence of partial atomic charge on oxidation state weakens with increasing oxidation state, which concurs with a previously proposed feedback effect. This correlation is then used to address oxidation states in Mn systems used as oxidants. Simulations of MnO2 polymorphs immersed in water give average oxidation states (AOS) in excellent agreement with experimental results, in that b-MnO2 has the highest AOS, a-MnO2 has an intermediate AOS, and d-MnO2 has the lowest AOS. Furthermore, the oxidation state varies substantially with the atom’s environment, and these structures include Mn(III) and Mn(V) species that are expected to be active. In regard to the MnO4−/HSO3−/O2 system that has been shown to be a highly effective oxidant, we propose a novel Mn complex that could give rise to the oxidative activity, where Mn(III) is stabilized by sulfite and dissolved O2 ligands. Our simulations also show that the O2 would be activated to O22- in this complex under acidic conditions, and could lead to the formation of OH radicals that serve as oxidants.