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Article ? AI-assigned paper type based on the abstract. Classification may not be perfect — flag errors using the feedback button. Tier 2 ? Original research — experimental, observational, or case-control study. Direct primary evidence. Environmental Sources Marine & Wildlife Sign in to save

Dark Reduction of Hg(II) by Dissolved Organic Matter Derived from Aging Microplastics: Mechanisms and Implications

Environmental Science & Technology 2025 7 citations ? Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count. Score: 53 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.
Xuetao Guo Wei Xing, Xuetao Guo Xuetao Guo Yong Shi, Xuetao Guo Yong Shi, Yong Shi, Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Yong Shi, Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Sarah Alotaibi, Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Lijie Zhang, Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xujun Liang, Xuetao Guo Xuetao Guo Xujun Liang, Xuetao Guo Lai Wei, Xuetao Guo Lai Wei, Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xujun Liang, Xujun Liang, Xujun Liang, Xujun Liang, Xujun Liang, Omowunmi A. Sadik, Lijie Zhang, Lijie Zhang, Xujun Liang, Xujun Liang, Xujun Liang, Xujun Liang, Xujun Liang, Xujun Liang, Xujun Liang, Xujun Liang, Xujun Liang, Xujun Liang, Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xujun Liang, Xujun Liang, Sarah Alotaibi, Omowunmi A. Sadik, Xujun Liang, Xuetao Guo Xuetao Guo Xujun Liang, Xuetao Guo Xujun Liang, Xujun Liang, Xujun Liang, Xuetao Guo Xuetao Guo Xujun Liang, Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xujun Liang, Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xujun Liang, Xujun Liang, Xuetao Guo Xuetao Guo Xuetao Guo Baohua Gu, Xujun Liang, Xujun Liang, Xujun Liang, Xujun Liang, Xujun Liang, Baohua Gu, Xujun Liang, Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xujun Liang, Xujun Liang, Xuetao Guo Xuetao Guo Xuetao Guo Xujun Liang, Xuetao Guo Xuetao Guo Xuetao Guo Baohua Gu, Xujun Liang, Xujun Liang, Xuetao Guo Xuetao Guo Xuetao Guo Lijie Zhang, Xuetao Guo Lijie Zhang, Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Omowunmi A. Sadik, Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo Xujun Liang, Xuetao Guo Xujun Liang, Xuetao Guo Xuetao Guo Xuetao Guo Xuetao Guo

Summary

Researchers discovered that dissolved organic matter released from photoaged microplastics can convert toxic mercury into a less reactive form through dark chemical reactions. The organic matter from aged polystyrene, PVC, and polylactic acid reduced over 30% of mercury within 10 minutes, outperforming natural river organic matter. The findings suggest that as microplastic pollution increases in waterways, it may significantly alter mercury cycling in aquatic environments.

Polymers
PLA PS PVC
Study Type Environmental

Dissolved organic matter (DOM) plays a critical role in the environmental cycling and transformation of mercury (Hg), primarily due to its strong reducing and complexing properties toward mercuric Hg(II). Microplastics-derived DOM (MPs-DOM), particularly that released during photoaging, represents an emerging source of DOM in aquatic environments. However, its capacity to mediate Hg(II) transformation remains largely unexplored. This study investigated dark reduction of Hg(II) by DOM released from aging polystyrene, polyvinyl chloride, and polylactic acid under simulated environmental conditions. The results show that, under dark conditions, DOM from photoaged MPs suspensions reduced over 30% of Hg(II) within 10 min, whereas DOM from dark-aged MPs suspensions exhibited negligible Hg(II) reduction activity. Further analyses showed that photoaging enhanced the electron-donating capacity of MPs-DOM by increasing phenol-like compounds, which promoted Hg(II) reduction via electron transfer through phenolic hydroxyl groups. Notably, MPs-DOM released during photoaging outperformed the Suwannee River natural organic matter (SRNOM) in reducing Hg(II), likely due to compositional differences in Hg(II)-complexing functional groups. When mixed together, elevated concentrations of MPs-DOM dominated over SRNOM, favoring Hg(II) reduction as the primary pathway. Given the growing prevalence of MPs-DOM in aquatic ecosystems and the persistence of dark reactions in light-limited environments, this study underscores the significant role of MPs-DOM in promoting dark Hg(II) reduction, highlighting a previously underrecognized pathway affecting Hg cycling.

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