Nitrate Dynamics in Relation to Lithology and Hydrologic Flow Path in a River Riparian Zone

The efficiency with which riparian zones remove nitrate (NO−3) from contaminated ground water can vary with landscape setting. This study was conducted to determine the influence of flood plain geometry, lithology, hydrologic flow path, and nitrate transport on mechanisms of nitrate depletion of con...

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Bibliographic Details
Published in:Journal of environmental quality 2000-07, Vol.29 (4), p.1075-1084
Main Authors: Devito, Kevin J., Fitzgerald, Dan, Hill, Alan R., Aravena, Ramon
Format: Article
Language:English
Subjects:
Applied sciences
Aquifers
Contamination
Deltas
Discharge
Dynamics
Earth sciences
Earth, ocean, space
Engineering and environment geology. Geothermics
Exact sciences and technology
Flood plains
Freshwater
Groundwater
Groundwaters
Hydrology
Lithology
Natural water pollution
Nitrates
Peat
Pollution
Pollution, environment geology
Rivers
Sand (material)
Sediments
Variability
Water treatment and pollution
Wetlands
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Summary:The efficiency with which riparian zones remove nitrate (NO−3) from contaminated ground water can vary with landscape setting. This study was conducted to determine the influence of flood plain geometry, lithology, hydrologic flow path, and nitrate transport on mechanisms of nitrate depletion of contaminated ground water. Patterns of NO−3−N, chloride, and dissolved organic carbon (DOC) concentrations and δ15N‐NO−3 and δ18O‐NO−3 values in combination with detailed piezometric head measurements were investigated in a river floodplain connected to a large upland sand aquifer in an agricultural region near Alliston, Ontario, Canada. Ground water discharging to the forested floodplain from the sand aquifer exhibited large spatial variability in NO−3−N concentrations (10–50 mg/L). The transport and depletion of NO−3 was strongly influenced by floodplain geometry and lithology. Little ground water flow occurred through the low‐conductivity matrix of peat in the floodplain. Plumes of NO−3‐rich ground water passed beneath the riparian wetland peat and flowed laterally in a 2‐ to 4‐m‐thick zone of permeable sands across the floodplain to the river. Analyses of the distribution of the NO−3−N concentrations, isotopes, and DOC within the floodplain indicate that denitrification occurred within the sand aquifer near the river where nitrate‐rich ground water interacted with buried channel sediments and surface water recharged from peat to the deeper sands. This study shows that the depth of permeable riparian sediments, ground water flow path, and the location of organic‐rich subsurface deposits may be more important than the width of vegetated strips in influencing the ability of riparian zones to remove nitrate.
ISSN:0047-2425
1537-2537
DOI:10.2134/jeq2000.00472425002900040007x