Schmidt Christian, Kumar Rohini, Yang Soohyun, Büttner Olaf
Department Hydrogeology, Helmholtz-Centre for Environmental Research - UFZ, Germany; Department of Aquatic Ecosystem Analysis, Helmholtz-Centre for Environmental Research - UFZ, Germany.
Department of Computational Hydrosystems, Helmholtz-Centre for Environmental Research - UFZ, Germany.
Sci Total Environ. 2020 Oct 1;737:139544. doi: 10.1016/j.scitotenv.2020.139544. Epub 2020 May 25.
Wastewater treatment plants (WWTP) are considered to be a point source of microplastic (particles <5 mm) for riverine environments. However, data on microplastic effluent concentrations in WWTPs is collected with a broad range of methods, which impede comparisons across data sets. We provide an estimate of the annual emissions of microplastic particles by WWTPs into the ten major river basins of Germany. We analyze the concentration patterns of microplastics among different stream orders resulting from the spatial organization of WWTPs along the river network. The local in-stream microplastic concentrations are estimated through a network model that accounts for routing of microplastics through the entire fluvial network under the assumption of no losses by sedimentation, entanglement or degradation. Previous studies have observed microplastic concentrations in treated WWTPs effluents ranging several orders of magnitude. In 19 studies reviewed (2016-2020), the concentrations of observed microplastic concentrations (size range between 10 and 5000 μm) in 79 WWTP effluents ranged between 4 ∗ 10 and 4.5 ∗ 10 items/m with a median of around 6400 items/m. The total, median microplastic load emitted by WWTPs in Germany is 7 ∗ 10 items/year. The simulated microplastic concentrations, on average, tend to increase with increasing stream order suggesting that the WWTP effluent fraction accumulates with a higher rate than discharge. Simulated WWTP-derived in-stream concentrations are higher than observed concentrations with all sources of microplastic, not only those from WWTPs. Observed microplastic concentrations in rivers as well as the considerably higher simulated, WWTP-derived microplastic concentration, even for low flow conditions, are approximately one order of magnitude below currently known toxic effect levels.
污水处理厂被认为是河流环境中微塑料(颗粒尺寸小于5毫米)的一个点源。然而,污水处理厂中微塑料排放浓度的数据是通过多种方法收集的,这妨碍了不同数据集之间的比较。我们估算了德国污水处理厂向该国十大流域排放微塑料颗粒的年排放量。我们分析了污水处理厂沿河网的空间布局导致的不同河流等级中微塑料的浓度模式。通过一个网络模型估算了局部河流中的微塑料浓度,该模型考虑了微塑料在整个河流网络中的流动路径,假设不存在因沉降、缠结或降解造成的损失。此前的研究观察到处理后的污水处理厂废水中的微塑料浓度相差几个数量级。在回顾的19项研究(2016 - 2020年)中,79个污水处理厂废水中观察到的微塑料浓度(尺寸范围在10至5000微米之间)在4×10至4.5×10个/立方米之间,中位数约为6400个/立方米。德国污水处理厂排放的微塑料总负荷中位数为7×10个/年。模拟的微塑料浓度平均而言往往随着河流等级的增加而增加,这表明污水处理厂排放的微塑料部分积累速度高于流量。模拟的源自污水处理厂的河流中微塑料浓度高于所有微塑料来源(不仅是来自污水处理厂的)的观测浓度。即使在低流量条件下,河流中观测到的微塑料浓度以及模拟的、源自污水处理厂的微塑料浓度明显更高,也比目前已知的毒性效应水平低大约一个数量级。
