化学
降级(电信)
氧化还原
活性氧
环境化学
催化作用
氧气
分解
微塑料
化学工程
腐植酸
聚合物
金属
电子转移
聚乳酸
生物降解
光化学
激进的
自动氧化
反应中间体
聚乙烯
无机化学
溶解有机碳
X射线光电子能谱
氧化磷酸化
双酚A
超氧化物
有机质
自行车
化学分解
作者
Rui Ding,Xiaoling Shan,Li Ding,Xinran Qiu,Bin Zhang,Xian Li,Xujun Liang,Xuetao Guo
标识
DOI:10.1021/acs.est.5c11616
摘要
Microplastics (MPs) persist in the environment due to their chemical inertness and structural stability, underscoring the need for effective degradation strategies. Here, we develop a surface-confined cascade system in which laccase is coupled with metal ions (Na+, Cu2+, Fe3+) to activate reactive oxygen species (ROS) for the degradation of three representative polymers─polyethylene (PE), polyethylene terephthalate (PET), and polylactic acid (PLA). The laccase-Cu2+ system (optimal at 0.1 mM) exhibited the strongest catalytic performance, inducing substantial oxidative transformation of MPs, as reflected by pronounced increases in O/C ratios and extensive disruption of polymer surface chemistry. Among the three polymers, PLA showed the highest degradation susceptibility owing to its lower crystallinity, labile aliphatic ester linkages, and enhanced responsiveness to ROS. In situ-generated MPs-derived dissolved organic matter (MPs-DOM) further regulated interfacial redox processes by accelerating electron transfer to metals, stabilizing reduced species, and sustaining ROS cycling. XPS and solution-phase analyses corroborated the DOM-assisted metal redox cycling at polymer interfaces. Multivariate modeling identified humic-like components and oxygenated moieties as the dominant ROS predictors. These findings reveal MPs-DOM as an active redox mediator that reinforces laccase-metal synergy, enabling persistent ROS generation and progressive MPs degradation.
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