Nitrate removal by floating treatment wetlands amended with spent coffee: A mesocosm-scale evaluation

M. G. Keilhauer; T. L. Messer; A. R. Mittelstet; T. G. Franti; J. R. Corman

doi:10.13031/trans.13431

Nitrate removal by floating treatment wetlands amended with spent coffee: A mesocosm-scale evaluation

M. G. Keilhauer, T. L. Messer, A. R. Mittelstet, T. G. Franti, J. R. Corman

Producción científica: Article › revisión exhaustiva

10 Citas (Scopus)

Resumen

The Midwestern U.S. is vulnerable to eutrophic conditions from high nutrient concentrations. Floating treatment wetlands (FTWs) are an innovative wetland design for nutrient removal from nonpoint sources and provide a unique in situ treatment. The objectives of this project were to quantify nitrate removal in traditional and carbon-amended FTWs planted with Midwestern plant species during the establishment year. Three greenhouse experiments were conducted throughout the growing season using 18 mesocosms. Two vegetation designs were evaluated: rush species (Juncus effusus and Juncus torreyi) and diverse species (Carex comosa, Carex vulpinoidea, Asclepias incarnata, J. effusus, J. torreyi, and Iris virginica). Spent coffee grounds were applied to 9 of the 18 mesocosms as a carbon amendment. Nitrate-N removal increased during the establishment growing season in the FTW systems (Spring: 15.0% to 17.3%, Summer 1: 82.8% to 92.6%, Summer 2: 86.4% to 94.7%). Nitrate-N removal was also impacted by carbon amendments (FTW without amendment: 82.8% to 94.7%, FTW with amendment: 88.4% to 96.1%). Carbon additions were found to enhance denitrifying conditions even in the absence of FTWs (decreased dissolved oxygen, increased available organic carbon). Significant differences in nitrate-N removal were not observed between FTW vegetation designs. This study provides new insight on the impacts of the growing season, plant species, and carbon amendments on FTW nitrate-N removal performance during the establishment year.

Idioma original	English
Páginas (desde-hasta)	1619-1630
Número de páginas	12
Publicación	Transactions of the ASABE
Volumen	62
N.º	6
DOI	https://doi.org/10.13031/trans.13431
Estado	Published - 2019

Nota bibliográfica

Publisher Copyright:
© 2019 American Society of Agricultural and Biological Engineers

Financiación

This project was supported with funding from the Robert B. Daugherty Water for Food Global Institute at the University of Nebraska-Lincoln. This project is based on research that was partially supported by the Nebraska Agricultural Experiment Station with funding from the Hatch capacity funding program (Accession No. 1014685) of the USDA National Institute of Food and Agriculture. Collaborators from the Nebraska Department of Environmental Quality made this project possible. Special thanks to Alexa Davis, Autumn Dunn, Rob Schroeder, and Sam Hansen for sampling and laboratory assistance.

Financiadores	Número del financiador
Alexa Davis
Nebraska Agricultural Experiment Station
Nebraska Department of Environmental Quality
US Department of Agriculture National Institute of Food and Agriculture, Agriculture and Food Research Initiative
University of Nebraska–Lincoln
Alabama Agricultural Experiment Station	1014685
Alabama Agricultural Experiment Station

ASJC Scopus subject areas

Forestry
Food Science
Biomedical Engineering
Agronomy and Crop Science
Soil Science

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abstract = "The Midwestern U.S. is vulnerable to eutrophic conditions from high nutrient concentrations. Floating treatment wetlands (FTWs) are an innovative wetland design for nutrient removal from nonpoint sources and provide a unique in situ treatment. The objectives of this project were to quantify nitrate removal in traditional and carbon-amended FTWs planted with Midwestern plant species during the establishment year. Three greenhouse experiments were conducted throughout the growing season using 18 mesocosms. Two vegetation designs were evaluated: rush species (Juncus effusus and Juncus torreyi) and diverse species (Carex comosa, Carex vulpinoidea, Asclepias incarnata, J. effusus, J. torreyi, and Iris virginica). Spent coffee grounds were applied to 9 of the 18 mesocosms as a carbon amendment. Nitrate-N removal increased during the establishment growing season in the FTW systems (Spring: 15.0\% to 17.3\%, Summer 1: 82.8\% to 92.6\%, Summer 2: 86.4\% to 94.7\%). Nitrate-N removal was also impacted by carbon amendments (FTW without amendment: 82.8\% to 94.7\%, FTW with amendment: 88.4\% to 96.1\%). Carbon additions were found to enhance denitrifying conditions even in the absence of FTWs (decreased dissolved oxygen, increased available organic carbon). Significant differences in nitrate-N removal were not observed between FTW vegetation designs. This study provides new insight on the impacts of the growing season, plant species, and carbon amendments on FTW nitrate-N removal performance during the establishment year.",

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AU - Franti, T. G.

AU - Corman, J. R.

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AB - The Midwestern U.S. is vulnerable to eutrophic conditions from high nutrient concentrations. Floating treatment wetlands (FTWs) are an innovative wetland design for nutrient removal from nonpoint sources and provide a unique in situ treatment. The objectives of this project were to quantify nitrate removal in traditional and carbon-amended FTWs planted with Midwestern plant species during the establishment year. Three greenhouse experiments were conducted throughout the growing season using 18 mesocosms. Two vegetation designs were evaluated: rush species (Juncus effusus and Juncus torreyi) and diverse species (Carex comosa, Carex vulpinoidea, Asclepias incarnata, J. effusus, J. torreyi, and Iris virginica). Spent coffee grounds were applied to 9 of the 18 mesocosms as a carbon amendment. Nitrate-N removal increased during the establishment growing season in the FTW systems (Spring: 15.0% to 17.3%, Summer 1: 82.8% to 92.6%, Summer 2: 86.4% to 94.7%). Nitrate-N removal was also impacted by carbon amendments (FTW without amendment: 82.8% to 94.7%, FTW with amendment: 88.4% to 96.1%). Carbon additions were found to enhance denitrifying conditions even in the absence of FTWs (decreased dissolved oxygen, increased available organic carbon). Significant differences in nitrate-N removal were not observed between FTW vegetation designs. This study provides new insight on the impacts of the growing season, plant species, and carbon amendments on FTW nitrate-N removal performance during the establishment year.

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Nitrate removal by floating treatment wetlands amended with spent coffee: A mesocosm-scale evaluation

Resumen

Nota bibliográfica

Financiación

ASJC Scopus subject areas

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