城市雨水花园系统中的雨水质量和微生物生态学

IF 2.6 Q2 WATER RESOURCES
Erin Corbett, U. Ijaz, Isla Jackson, Vernon R. Phoenix
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引用次数: 0

摘要

雨水花园是传统排水系统的替代品,能够降低洪水风险,减少雨水对环境的污染。雨水花园清除污染物的动力来自物理过程(如过滤和沉淀)和土壤微生物的生物代谢过程。为了更好地了解雨水花园的性能,本研究利用来自繁忙道路的真实雨水花园,探讨了雨水花园对污染去除、微生物组成和功能的影响。每个雨水花园都有不同的粒径和水力传导性,因为这些参数被认为会影响污染清除。所有四个雨水花园都能减少雨水中的污染物负荷,降低溶解金属、悬浮固体和化学需氧量的浓度。值得注意的是,冬季撒盐并不会导致雨水花园释放出溶解金属,这表明在冬季撒盐期间,雨水花园可以继续减少污染物负荷。不同的测试土壤在污染物去除方面存在一些差异,但总体而言,根据颗粒大小和水力传导性,所有雨水花园的表现大体相似,无法确定明确的趋势。雨水花园土壤改变了雨水中的微生物群落,与进水相比,出水的分类更均匀,功能更丰富。土壤的功能丰富度也高于输入水,这表明雨水花园中的微生物能够比流入水中的微生物发挥更广泛的功能。出水和土壤微生物学受取样日期的影响比受土壤粒径的影响更大,这可能是土壤群落成熟和随时间变化的结果。随着越来越多的雨水花园投入使用,以应对气候变化带来的洪水问题,确保环境免受雨水中城市污染物的影响非常重要。这项研究的结果进一步凸显了雨水花园承担这一重要任务的能力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Stormwater quality and microbial ecology in an urban rain garden system
Rain gardens are an alternative to traditional drainage, able to lower flood risk and reduce environmental contamination from stormwater. Removal of contaminants by rain gardens is driven by both physical processes (such as filtration and sedimentation) and biological metabolic processes by soil microorganisms. To better understand rain garden performance, this study explored the impact of rain gardens on pollution removal and microbial composition and function using rain gardens fed real stormwater from a busy road. Each rain garden had different grain size and hydraulic conductivities as these parameters have been argued to impact pollution removal. All four rain gardens were able to reduce the contaminant load in the stormwaters, reducing the concentration of dissolved metals, suspended solids and chemical oxygen demand. Significantly, road salting in the winter did not cause dissolved metals to be released from the rain gardens, suggesting that rain gardens can continue to reduce contaminant loads during winter salting regimes. Some variation in pollutant removal was seen between the soils tested, but overall no clear trend could be identified based on grain size and hydraulic conductivity with all rain gardens performing broadly similarly. The rain garden soil altered the microbial community in the stormwater, resulting in greater taxonomic evenness and functional richness in the effluent water compared to the influent. Functional richness of the soils was also higher than that of the input waters, indicating that the microbes in the rain gardens were able to perform a wider range of functions than those of the influent. Effluent and soil microbiology was more impacted by sampling date than soil grain size, which may be a result of the soil communities maturing and changing over time. As greater numbers of rain gardens are installed to tackle flooding from climate change, it is important to ensure the environment is protected from urban contaminants in the stormwater. The results in this study further highlight the ability of rain gardens to undertake this important task.
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来源期刊
Frontiers in Water
Frontiers in Water WATER RESOURCES-
CiteScore
4.00
自引率
6.90%
发文量
224
审稿时长
13 weeks
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