Impact of seasonal changes in stream metabolism on nitrate concentrations in an urban stream

Nitrate (NO₃⁻) dynamics in urban streams differ from many natural streams due to stormwater runoff, sewage inputs, decreased groundwater discharge, often limited hyporheic exchange, increased primary productivity, and limited carbon input. We investigated NO₃⁻ dynamics in a first-order urban stream...

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Bibliographic Details
Published inBiogeochemistry Vol. 133; no. 3; pp. 317 - 331
Main Authors Ledford, Sarah H., Lautz, Laura K., Vidon, Philippe G., Stella, John C.
Format Journal Article
LanguageEnglish
Published Cham Springer Science + Business Media 01.05.2017
Springer International Publishing
Springer Nature B.V
Subjects
Algae
Algal mats
Annual variations
Aquatic plants
Autotrophy
Biogeosciences
Canopies
Canopy
Density
Dynamics
Earth and Environmental Science
Earth Sciences
Ecosystems
Environmental Chemistry
Geomorphology
Ground water
Groundwater
Groundwater discharge
Groundwater runoff
Headwaters
Herbivores
Heterotrophy
Leaves
Life Sciences
Metabolism
Natural streams
Nitrates
Organic matter
ORIGINAL PAPERS
Primary production
Rivers
Runoff
Seasonal variation
Seasonal variations
Sewage
Shading
Spring
Storm runoff
Stormwater
Stormwater management
Stormwater runoff
Streams
Summer
Temperature effects
Uptake
Urban areas
Water analysis
Water sampling
Winter
Nitrate
Nutrient uptake
Urban water chemistry
Seasonality
Surface water
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Summary:Nitrate (NO₃⁻) dynamics in urban streams differ from many natural streams due to stormwater runoff, sewage inputs, decreased groundwater discharge, often limited hyporheic exchange, increased primary productivity, and limited carbon input. We investigated NO₃⁻ dynamics in a first-order urban stream in Syracuse, NY, which has urbanized headwaters and a geomorphologically natural downstream section. Twice-monthly water sampling, NO₃⁻ injection tests, NO₃⁻ isotopic analysis, filamentous algae mat density, and riparian shading were used to identify processes regulating NO₃⁻ dynamics in the stream tests, NO₃⁻ isotopic analysis, filamentous algae mat density, and riparian shading were used to identify processes regulating NO₃⁻ dynamics in the stream over a 12-month period. The urban headwater reach had low NO₃⁻ (0.006–0.2 mg N/L) in the spring through fall, with a minimum uptake length of 900 m, no canopy cover, and high algae mat density. The downstream natural reach (100% canopy cover during the summer and low algae mat density) had nitrate concentrations between 0.6 and 1.2 mg N/L from winter to summer, which decreased during autumn leaf-off. In the urban reach, autotrophic uptake by filamentous green algae is a major NO₃⁻ sink in summer. In the natural reach, the addition of organic matter to the stream at leaf-off led to a decrease in NO₃⁻ concentration followed by an increase in NO₃⁻ concentration in winter as gross primary productivity decreased. This study shows that the balance between autotrophy and heterotrophy in urban streams is variable and depends on an interplay of drivers such as temperature, light, and carbon inputs that are mediated by the riparian ecosystem. variable and depends on an interplay of drivers such as temperature, light, and carbon inputs that are mediated by the riparian ecosystem.
ISSN:0168-2563
1573-515X
DOI:10.1007/s10533-017-0336-7