Collaborative Research: Quantifying Nitrogen Uptake in Bioretention Designed for Semiarid Climates

合作研究：量化半干旱气候生物滞留中的氮吸收

• 批准号: 1133524
• 负责人: Christine Pomeroy
• 金额: $ 33.86万
• 依托单位: University of Utah
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2011
• 资助国家: 美国
• 起止时间: 2011-10-01 至 2016-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1133524&HistoricalAwards=false
• 关键词: Collaborative; Research; Quantifying; Nitrogen; Uptake

1133524 PI PomeroyBioretention is a low impact development management strategy that employs engineered plant communities to reduce the impact of urbanization on stormwater runoff volumes and pollution. The proposed research expands the evaluation of bioretention and is guided by the theory that urban ecosystems can be engineered following basic ecological principles to sustainably perform a necessary service to society. The overarching goal of this research is to improve the understanding of how engineered ecosystems function in urban settings in order to optimize bioretention design by maximizing the service of watershed protection and minimizing the resources necessary to sustain the engineered ecosystem. This overarching research goal will be achieved by conducting two sets of experiments: (1) a two-year study to quantify nitrogen (N) treatment in bioretention over time and (2) an isotopic labeling experiment to describe plant contributions to the treatment processes for organic and inorganic N. Three plant community types will be tested using nine bioretention cells: a semi-arid upland shrub community, a wetland community, and a control with no plants. These experiments will test the following hypotheses: (1) the addition of vegetation cover will result in a greater overall retention of N, even under conditions where multiple stormwater events increase the residual level of N within each bioretention cell, (2) in cells without vegetation, the concentration of inorganic N in the effluent will be greater than the concentration of inorganic N in the influent, (3) in bioretention cells with vegetation, the concentration of inorganic N in the effluent will be less that the concentration of inorganic N in the influent. The PI will monitor the nitrogen treatment performance and plant productivity of the three plant communities to model how each community responds to repeated inundations of urban stormwater in a semi-arid climate. The results of these studies will be combined to predict long-term performance of bioretention in arid and semi-arid climates. The isotopic labeling studies will identify treatment rates and pathways of organic and inorganic N by recovering the labeled N in the plant tissue, soil materials or garden effluent. This will determine if plants can take up inorganic nitrogen from stormwater sources rapidly without transformation during wetting events, and that through complex interactions with soil microbes, organic nitrogen will be biologically mineralized then slowly taken up by plants between wetting events. In terms of the broader impacts, the findings of this research will provide technical support to improve design and expand the implementation of bioretention in the arid and semi-arid west. Better knowledge of how different plant communities process N on the scale of individual storm events and over time is critical to providing design recommendations that ensure bioretention performance when implemented broadly. Implementation of bioretention in the arid and semi-arid west will allow urbanization to occur while protecting fragile ecosystems adjacent to expanding developments. Planned outreach efforts under this research project include (1) two workshops provided for local- and state-level officials within Utah, demonstrating the functionality, economics, and environmental protection potential of bioretention to policy makers, (2) three University of Utah student-organized workshops targeted to stormwater professionals to address design, plant selection, and environmental benefits of bioretention in semi-arid climates, (3) national dissemination of bioretention workshop materials via a website, and (4) integration of the research findings into the curriculum of existing urban ecology, water policy, and water resources engineering graduate and undergraduate courses.

1133524 PiPomeroyBirement是一种低影响的开发管理策略，采用工程植物群落来减少城市化对雨水径流量和污染的影响。这项拟议的研究扩展了生物保留性的评估，并以以下理论为指导：城市生态系统可以按照基本的生态学原则进行工程设计，以可持续地为社会提供必要的服务。这项研究的总体目标是提高对工程生态系统如何在城市环境中发挥作用的理解，以便通过最大化流域保护服务和最大限度地减少维持工程生态系统所需的资源来优化生物保育设计。这一总体研究目标将通过进行两组实验来实现：(1)为期两年的研究，以量化氮(N)处理随时间的变化；(2)同位素标记实验，描述植物对有机和无机N处理过程的贡献。三种植物群落类型将使用9个生物保留细胞进行测试：半干旱旱地灌木群落、湿地群落和没有植物的对照。这些实验将检验以下假设：(1)增加植被覆盖将导致更大的总体N的滞留，即使在多次暴雨事件增加每个生物保育单元内的N的残留水平的情况下；(2)在没有植被的细胞中，出水中无机N的浓度将大于进水中的无机N浓度；(3)在有植被的生物保育细胞中，出水中的无机N浓度将小于进水中的无机N浓度。PI将监测三个植物群落的氮素处理性能和植物生产力，以模拟每个群落如何应对半干旱气候中反复泛滥的城市雨水。这些研究的结果将结合起来预测生物保育在干旱和半干旱气候中的长期表现。同位素标记研究将通过恢复植物组织、土壤材料或花园污水中标记的N来确定有机和无机N的处理速度和途径。这将决定植物能否在湿润事件期间迅速吸收雨水来源中的无机氮而不发生变化，以及通过与土壤微生物的复杂相互作用，有机氮将被生物矿化，然后在湿润事件期间被植物缓慢吸收。就更广泛的影响而言，本研究成果将为改进西部干旱半干旱地区生物保育的设计和推广提供技术支持。更好地了解不同植物群落如何在单个风暴事件的规模上以及随着时间的推移处理N，对于提供设计建议以确保广泛实施时的生物保持性能至关重要。在干旱和半干旱的西部地区实施生物保护将使城市化得以实现，同时保护毗邻不断扩大的开发项目的脆弱生态系统。根据这一研究项目计划开展的外联活动包括：(1)在犹他州为地方和州一级的官员提供2个讲习班，向决策者展示生物保护区的功能、经济和环境保护潜力；(2)由犹他大学的学生组织3个讲习班，面向雨水专业人员，讨论半干旱气候下生物保护区的设计、植物选择和环境效益；(3)通过网站在全国范围内传播生物保护区讲习班材料，以及(4)将研究成果纳入现有城市生态学、水政策和水资源工程研究生和本科课程的课程。