The widespread occurrence of carcinogenic arsenic (As) and eutrophication-driving phosphorus (P) in aquatic environments poses severe risks, particularly in small subtropical estuaries characterized by hydrological constraints and limited self-purification capacity. Nevertheless, the synergistic geochemical cycle coupling As and P with manganese (Mn), iron (Fe), and sulfur (S), and their seasonal release mechanisms, remain to be fully elucidated. In this study, the diffusive gradients in thin films (DGT) technique were employed to simultaneously monitor the high-resolution spatiotemporal mobilization of As and P in two small estuaries. Results showed that P mobility was governed by Fe redox cycling (r = 0.8, p < 0.01), being immobilized through adsorption onto Fe (hydr)oxides under oxic conditions in spring and released via reductive dissolution of Fe (hydr)oxides driven by summer heat and winter inputs of organic matter (OM). While As mobility was regulated by both Fe and Mn redox cycles, and showing similar seasonal patterns to P which was sequestrated in spring and mobilized in summer and winter. Locally sulfidic conditions fuelled P mobilization via reductive S-Fe-P coupling, but immobilized As through formation of solid metallic sulfide. Notably, this study highlights elevated winter release risks in such small estuaries, where seasonal OM and Fe/Mn (hydr)oxides inputs stimulate iron reduction and enhance sediment resupply in winter, resulting in significant activation of P and As. These findings emphasize the critical role of seasonal redox shifts and deposition of materials input in driving As and P mobility in dynamic estuarine sediments.
Keywords: Arsenic, Phosphorus, Redox-sensitive elements, Sediment porewater, Small estuaries
Marine pollution bulletin
Journal Article
English
41997064
Guideline Central and select third party use “cookies” on this website to enhance the user experience.
This technology helps us gather statistical and analytical information to optimize the relevant content for you.
The user also has the option to opt-out which may have an effect on the browsing experience.