Molecular-weight-dependent redox cycling of humic substances of paddy soils over successive anoxic and oxic alternations

Humic substances (HSs) are critical to regulating methane cycling in temporary anoxic systems because their redox-active functional groups can sustainably shuttle electrons from microorganisms to oxygen (O-2) over successive anoxic and oxic alternations. Whether the relative amount of these redox-active functional groups involved in redox cycles is associated with the overall chemical structures of HS still remains poorly understood. In this study, variations in the reducing capacities (RCs) of HSs extracted from paddy soils were monitored over consecutive cycles of reduction by iron-reducing microorganisms and oxidation by O-2. Our results show that about 10-40% of the microbially reduced redox-active moieties within HS, which were reoxidised by O-2, cannot restore the same redox state as those before microbial reduction. The restoration extents of RCs of HSs after microbial reduction and O-2 reoxidation were greatly negatively correlated with average molecular weight (AMW). The microbially reduced HSs having large AMWs (>1,000 Da) were more kinetically difficult to restore by O-2 from a reduced state to an oxidised state than were those having small AMWs (