Riparian zone denitrification affects nitrogen flux through a tidal freshwater river

Tidal freshwater zones (TFZ) of coastal rivers link terrestrial watersheds to the ocean and are characterized by large, regularly inundated riparian zones. We investigated the effect of riparian denitrification on nitrogen flux in the TFZ Newport River, North Carolina (U.S.A.) by developing an empir...

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Bibliographic Details
Published in:Biogeochemistry 2008-12, Vol.91 (2-3), p.133-150
Main Authors: Ensign, Scott H, Piehler, Michael F, Doyle, Martin W
Format: Article
Language:English
Subjects:
Biogeochemistry
Biogeosciences
Cores
Denitrification
Earth and Environmental Science
Earth Sciences
Earth, ocean, space
Ecosystems
Environmental Chemistry
Exact sciences and technology
Floodplains
Fluctuations
Fresh water
Freshwater
Geochemistry
Life Sciences
Marine and continental quaternary
Mud flats
Nitrates
Nitrogen
Oxidation
Oxidation-reduction potential
Riparian areas
Riparian ecology
River water
Rivers
Sediments
Soil water
Surficial geology
Topography
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Summary:Tidal freshwater zones (TFZ) of coastal rivers link terrestrial watersheds to the ocean and are characterized by large, regularly inundated riparian zones. We investigated the effect of riparian denitrification on nitrogen flux in the TFZ Newport River, North Carolina (U.S.A.) by developing an empirical model of denitrification and parameterizing it using measured denitrification rates, sediment oxidation-reduction potential dynamics, and riparian topography. Denitrification rates were measured monthly in laboratory-incubated sediment cores by using a membrane inlet mass spectrometer to assess net water-borne N₂ flux from the cores. Annual average rates of denitrification in three intertidal riparian habitats, emergent marsh, mudflat, and hardwood forest, were 1864, 1956, and 2018 μg m⁻² h⁻¹, respectively. Laboratory experiments and in-situ monitoring revealed that the temporal lag between tidal inundation and reduced, denitrifying conditions was 4-5 h. Field measurements and remotely sensed data showed that the inundated surface area during high tide was three times greater than that at low tide. By combining data on denitrification, oxidation-reduction potential, and topography, the model predicted that the daily denitrification flux constituted 2-15% of the daily riverine nitrate flux during most of the year and >100% during low discharge periods. Current regional and global nitrogen budgets thus may overestimate nitrogen delivery to the ocean by not accounting for the TFZ denitrification.
ISSN:0168-2563
1573-515X
DOI:10.1007/s10533-008-9265-9