Factors Controlling Transport Dynamics of Microplastics in Streams

IF 4.8 Q1 ENVIRONMENTAL SCIENCES
Nadia Dikareva*,  and , Kevin S. Simon, 
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Abstract

Streams are the primary conduits through which microplastics are transported from land to sea. Attributes of the plastic particles and of the streams are both likely to influence how microplastic moves, but there are few empirical studies of microplastic transport dynamics in real systems. We adopted the spiralling technique commonly used to measure nutrient cycling in streams to quantify transport distances and deposition velocities of microplastics in streams with varying geomorphological structure and level of human modification. We conducted pulse releases of trace amounts of three size classes of five different polymers spanning a density gradient in 15 streams. The streams were typical of the range of human modification in urban environments, from seminatural to highly modified. Transport distances of microplastic ranged from <1 to 111 m, with distances declining with particle size. Neutrally buoyant polymers had the longest transport distances and lowest deposition velocities. Streams that had been modified into concrete channels were the most effective in transporting microplastics downstream, as indicated by relatively low deposition velocities and long transport distances of microplastics. Our results suggest that the movement of microplastic pollution in streams depends on the physical characteristics of the stream more than on plastic properties.

Abstract Image

控制溪流中微塑料迁移动力学的因素
溪流是微塑料从陆地向海洋迁移的主要通道。塑料微粒和溪流的属性都可能影响微塑料的迁移方式,但对实际系统中微塑料迁移动态的实证研究却很少。我们采用了测量溪流营养循环的常用螺旋技术,以量化微塑料在不同地貌结构和人为改造程度的溪流中的迁移距离和沉积速度。我们在 15 条溪流中进行了跨越密度梯度的微量脉冲释放,释放了三种尺寸的五种不同聚合物。这些溪流是城市环境中典型的人为改造范围,从半自然到高度改造。微塑料的迁移距离从 1 米到 111 米不等,迁移距离随着颗粒大小的增加而减小。中浮力聚合物的迁移距离最长,沉积速度最低。被改造成混凝土河道的溪流在向下游输送微塑料方面最为有效,这一点从微塑料相对较低的沉积速度和较长的输送距离可以看出。我们的研究结果表明,微塑料污染在溪流中的移动更多地取决于溪流的物理特性,而非塑料特性。
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CiteScore
5.40
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0.00%
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