Pollutant accumulation and microbial community evolution in rain gardens with different drainage types at field scale

Zhang, Zhaoxin; Zhang, Yang; Li, Jiake; Sun, Yingying; Liu, Zhe

doi:10.1038/s41598-023-48255-6

Cited by 4 publications

(1 citation statement)

References 45 publications

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“…Rain gardens are one of the LID measures that are designed and constructed through the design and construction of artificial gardens or landscapes, usually consisting of vegetation, permeable soils, and drainage facilities, with the aim of reducing stormwater runoff, improving water quality, increasing urban green space, and enhancing the resilience of urban ecosystems [9]. Current research on rain gardens focuses on hydrologic simulation studies [10], soil infiltration studies [11], pollutant retention capacity studies [12], hydrologic effects of different plant applications [13], and studies on low-carbon construction and application of rain gardens [14]. Due to the strong territoriality of rain garden plants, the current research on plant selection and design of rain gardens is weak, and there are few quantitative studies under multi-objective requirements.…”

Section: Introductionmentioning

confidence: 99%

A Study on Plant Selection for Low-Carbon Rain Gardens Based on an AHP-TOPSIS Model

Zhao,

Chen,

Han

et al. 2024

Sustainability

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Low-impact development (LID) measures are crucial for solving water environment problems during sponge city construction. Optimizing LID measures to meet multi-objective demands is essential for achieving low-carbon and green operation of sponge cities under the goal of ‘dual carbon’. To select the optimal rain garden plants suitable for the construction of a coastal sponge low-carbon city, a set of AHP-TOPSIS applicability assessments was constructed. The assessment index system comprises three main categories of indices: economic cost, ecological benefit, and environmental adaptability. The hierarchical analysis method (AHP) was used to construct a plant evaluation system from three decision-making levels and eleven criterion levels. This system assigned weights to each index in the index system. Subsequently, the distance between the superior and inferior solutions (TOPSIS) was used to evaluate the overall performance of 14 tree species, 10 shrub species, and 12 herbaceous plant species commonly found in rain gardens in a coastal city in China, so as to identify the optimal plants to meet the target demand of low-carbon rain garden construction.

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Section: Introductionmentioning

confidence: 99%

A Study on Plant Selection for Low-Carbon Rain Gardens Based on an AHP-TOPSIS Model

Zhao,

Chen,

Han

et al. 2024

Sustainability

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Emerging technologies and supporting tools for earthquake disaster management: A perspective, challenges, and future directions

Abdalzaher,

Krichen,

Falcone

2024

Progress in Disaster Science

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Stormwater quality and microbial ecology in an urban rain garden system

Corbett,

Ijaz,

Jackson

et al. 2024

Front. Water

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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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Pollutant accumulation and microbial community evolution in rain gardens with different drainage types at field scale

Cited by 4 publications

References 45 publications

A Study on Plant Selection for Low-Carbon Rain Gardens Based on an AHP-TOPSIS Model

A Study on Plant Selection for Low-Carbon Rain Gardens Based on an AHP-TOPSIS Model

Emerging technologies and supporting tools for earthquake disaster management: A perspective, challenges, and future directions

Stormwater quality and microbial ecology in an urban rain garden system

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