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Pore-Scale Visualized Transport and Retention of Fibrous and Fragmental Microplastics in Porous Media under Various Surfactant Conditions

Environmental Science & Technology 2024 12 citations ? Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count. Score: 50 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.

Shunan Dong, Shunan Dong, Bin Gao, Shunan Dong, Shunan Dong, Qianhui Yu, Shunan Dong, Shunan Dong, Shunan Dong, Shunan Dong, Shunan Dong, Yulu Yu, Yulu Yu, Xiaoting Su, Xiaoting Su, Shunan Dong, Shunan Dong, Shunan Dong, Liting Sheng, Liting Sheng, Liting Sheng, Liting Sheng, Liting Sheng, Liting Sheng, Xiaoting Su, Shunan Dong, Xiaoting Su, Shunan Dong, Xiaoting Su, Liting Sheng, Liting Sheng, Yuanyuan Sun, Xiaoting Su, Liting Sheng, Bin Gao, Xiaoting Su, Qianhui Yu, Liting Sheng, Xiaoting Su, Xiaoting Su, Xiaoting Su, Qianhui Yu, Bin Gao, Yulu Yu, Shunan Dong, Qianhui Yu, Yuanyuan Sun, Yulu Yu, Bin Gao, Bin Gao, Liting Sheng, Yulu Yu, Jichun Wu Jichun Wu Jichun Wu Liting Sheng, Shunan Dong, Yulu Yu, Yulu Yu, Yulu Yu, Yuanyuan Sun, Yulu Yu, Jichun Wu Yuanyuan Sun, Yulu Yu, Jichun Wu Bin Gao, Jichun Wu Jichun Wu Jichun Wu Jichun Wu Jichun Wu Jichun Wu Bin Gao, Jichun Wu Jichun Wu

Summary

Researchers used a pore-scale visualization system to observe how fibrous and fragmental microplastics move through porous media under different surfactant conditions. They found that fibrous microplastics had lower mobility because they tend to entangle and clog pore spaces, while fragmental particles moved more freely and responded differently to various surfactant types. The study provides detailed insight into how microplastic shape and surface chemistry influence their transport through soil and groundwater systems.

For advancing current knowledge on the transport of microplastics (MPs) in the environment, this study used a real-time pore-scale visualization and quantitative system to examine the motions and mobility of fibrous and fragmental MPs under various surfactant (AEO, CTAC, and AES) and electrolyte conditions. The videos showed that fibrous MPs formed tangles through entanglement, which moved in an axial direction aligned with the flow streamline. Both fibrous and fragmental MPs showed suspended movement as well as surface movement (e.g., sliding, rolling, and saltating) in the porous media. Some deposited fibrous MPs showed flexible deformation due to shear flow. Compared to fragmental MPs, fibrous MPs showed lower mobility due to the tendency to deposit and clog the porous media. The mobility of fragmental MPs was enhanced in the presence of AEO but remained relatively unchanged with AES. In the presence of CTAC, the mobility of fragmental MPs was slightly inhibited under low ionic strength (IS) conditions but remarkably enhanced under high IS conditions. However, the mobility of fibrous MPs was largely unaffected by the surfactants. Both the numerical model and FDLVO calculations effectively described the transport and deposition of MPs in porous media.

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