Field evaluation of a biochar-amended stormwater filtration system for retention of nutrients, metals, and Escherichia coli†

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Bridget A. Ulrich, Karina Weelborg, Tadele M. Haile, Udai B. Singh and Joe Magner
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引用次数: 0

Abstract

The objective of this study was to assess the impacts of biochar and iron-enhanced sand (IES) on the comprehensive contaminant retention performance of a field-scale stormwater filtration system. The system distributed runoff from a parking lot into three filters containing sand, sand amended with biochar (custom-produced via pyrolysis of red pine wood chips at 550 °C), or IES. Over the first two field seasons of operation flow into the testbed and out of each filter were continuously monitored, and influent and effluent samples were collected during 21 precipitation events and analyzed for various contaminants and water quality parameters. To account for variations in flow distribution between the filters, long-term filter performance was assessed based on comparison of apparent cumulative input and output contaminant loads over the study duration (i.e., apparent cumulative contaminant retention). The IES filter showed the most effective phosphorous retention performance (>90% net retention of total phosphorus, TP), reflecting results from previous studies. The biochar-amended filter showed improved retention of zinc and total inorganic nitrogen (TIN) relative to the sand filter, which may be attributed to: (i) enhanced electrostatic interactions between zinc and oxygen-containing functional groups on the biochar surface, and (ii) improved attenuation of ammonia-N due to reduced nitrification and/or enhanced adsorption of ammonium. The biochar-amended filter did not show improved retention of total organic carbon or Escherichia coli, in contrast to some previous studies, potentially due to differences in biochar material properties (e.g., reduced hydrophobic interactions due to the custom biochar's relatively polar surface chemistry) or operational conditions (e.g., differences in flow rate or biofilm development between the filters). These findings demonstrate the complexities surrounding the application of biochar as a stormwater filter material for broad contaminant removal, and warrant the development of best practice recommendations for biochar selection and performance testing.

Abstract Image

Abstract Image

实地评估生物炭添加剂雨水过滤系统对营养物质、金属和大肠埃希氏菌的截留作用
本研究的目的是评估生物炭和铁质强化砂(IES)对现场规模雨水过滤系统的综合污染物截留性能的影响。该系统将停车场的径流分流到三个过滤器中,过滤器中分别装有沙子、生物炭(通过在 550 °C 下热解红松木屑定制生产)或 IES。在运行的前两个季节,对进入试验台和流出每个过滤器的流量进行了连续监测,并在 21 次降水过程中收集了进水和出水样本,分析了各种污染物和水质参数。为了考虑过滤器之间流量分布的变化,根据研究期间的表观累积输入和输出污染物负荷(即表观累积污染物滞留量)的比较,对过滤器的长期性能进行了评估。IES 过滤器显示出最有效的磷截留性能(总磷净截留率达 90%),反映了之前研究的结果。与砂滤器相比,经生物炭改良的滤器对锌和无机氮总量(TIN)的截留效果更好,这可能归因于(i) 生物炭表面的锌和含氧官能团之间的静电相互作用增强,(ii) 由于硝化作用减弱和/或氨的吸附作用增强,氨氮的衰减得到改善。与之前的一些研究相比,经生物炭改良的过滤器对总有机碳或大肠埃希氏菌的截留率并没有提高,这可能是由于生物炭材料特性的不同(例如,定制生物炭相对极性的表面化学性质减少了疏水相互作用)或运行条件的不同(例如,过滤器之间流速或生物膜发展的不同)造成的。这些研究结果表明,将生物炭用作雨水过滤材料以广泛去除污染物的应用非常复杂,因此有必要为生物炭的选择和性能测试制定最佳实践建议。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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