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Influence of urban river restoration on nitrogen dynamics at the sediment-water interface

Influence of urban river restoration on nitrogen dynamics at the sediment-water interface
Influence of urban river restoration on nitrogen dynamics at the sediment-water interface
River restoration projects focused on altering flow regimes through use of in-channel structures can facilitate ecosystem services, such as promoting nitrogen (N) storage to reduce eutrophication. In this study we use small flux chambers to examine ammonium (NH4+) and nitrate (NO3-) cycling across the sediment-water interface. Paired restored and unrestored study sites in 5 urban tributaries of the River Thames in Greater London were used to examine N dynamics following physical disturbances (0–3 min exposures) and subsequent biogeochemical activity (3–10 min exposures). Average ambient NH4+ concentrations were significantly different amongst all sites and ranged from 28.0 to 731.7 μg L-1, with the highest concentrations measured at restored sites. Average NO3- concentrations ranged from 9.6 to 26.4 mg L-1, but did not significantly differ between restored and unrestored sites. Average NH4+ fluxes at restored sites ranged from -8.9 to 5.0 μg N m-2 sec-1, however restoration did not significantly influence NH4+ uptake or regeneration (i.e., a measure of release to surface water) between 0–3 minutes and 3–10 minutes. Further, average NO3- fluxes amongst sites responded significantly between 0–3 minutes ranging from -33.6 to 97.7 μg N m-2 sec-1. Neither NH4+ nor NO3- fluxes correlated to sediment chlorophyll-a, total organic matter, or grain size. We attributed variations in overall N fluxes to N-specific sediment storage capacity, biogeochemical transformations, potential legacy effects associated with urban pollution, and variations in river-specific restoration actions
1932-6203
Lavelle, Anna M.
6900ae66-d111-4b6f-9c8f-8948d3d5c2b1
Bury, Nic R.
696daba0-5cc9-444c-be9a-c678808712c6
O’Shea, Francis T.
3540c4c4-85b6-4364-8bc5-15a11419210b
Chadwick, Michael A.
8586bda9-02f6-4f01-a60e-bc4a611782d3
Iglesias, Miguel Cañedo-Argüelles
368cc1f8-d6dd-484a-b147-f23195a6eea5
Lavelle, Anna M.
6900ae66-d111-4b6f-9c8f-8948d3d5c2b1
Iglesias, Miguel Cañedo-Argüelles
368cc1f8-d6dd-484a-b147-f23195a6eea5
Bury, Nic R.
696daba0-5cc9-444c-be9a-c678808712c6
O’Shea, Francis T.
3540c4c4-85b6-4364-8bc5-15a11419210b
Chadwick, Michael A.
8586bda9-02f6-4f01-a60e-bc4a611782d3

Lavelle, Anna M., Bury, Nic R., O’Shea, Francis T. and Chadwick, Michael A. , Iglesias, Miguel Cañedo-Argüelles (ed.) (2019) Influence of urban river restoration on nitrogen dynamics at the sediment-water interface. PLoS ONE, 14 (3), [e0212690]. (doi:10.1371/journal.pone.0212690).

Record type: Article

Abstract

River restoration projects focused on altering flow regimes through use of in-channel structures can facilitate ecosystem services, such as promoting nitrogen (N) storage to reduce eutrophication. In this study we use small flux chambers to examine ammonium (NH4+) and nitrate (NO3-) cycling across the sediment-water interface. Paired restored and unrestored study sites in 5 urban tributaries of the River Thames in Greater London were used to examine N dynamics following physical disturbances (0–3 min exposures) and subsequent biogeochemical activity (3–10 min exposures). Average ambient NH4+ concentrations were significantly different amongst all sites and ranged from 28.0 to 731.7 μg L-1, with the highest concentrations measured at restored sites. Average NO3- concentrations ranged from 9.6 to 26.4 mg L-1, but did not significantly differ between restored and unrestored sites. Average NH4+ fluxes at restored sites ranged from -8.9 to 5.0 μg N m-2 sec-1, however restoration did not significantly influence NH4+ uptake or regeneration (i.e., a measure of release to surface water) between 0–3 minutes and 3–10 minutes. Further, average NO3- fluxes amongst sites responded significantly between 0–3 minutes ranging from -33.6 to 97.7 μg N m-2 sec-1. Neither NH4+ nor NO3- fluxes correlated to sediment chlorophyll-a, total organic matter, or grain size. We attributed variations in overall N fluxes to N-specific sediment storage capacity, biogeochemical transformations, potential legacy effects associated with urban pollution, and variations in river-specific restoration actions

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More information

Accepted/In Press date: 7 February 2019
Published date: 13 March 2019
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Identifiers

Local EPrints ID: 475596
URI: http://eprints.soton.ac.uk/id/eprint/475596
DOI: doi:10.1371/journal.pone.0212690
ISSN: 1932-6203
PURE UUID: bf3a20ac-3708-4813-968e-ede90cd94031
ORCID for Nic R. Bury: ORCID iD orcid.org/0000-0001-6048-6338

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Date deposited: 22 Mar 2023 17:32
Last modified: 17 Mar 2024 04:14

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Contributors

Author: Anna M. Lavelle
Editor: Miguel Cañedo-Argüelles Iglesias
Author: Nic R. Bury ORCID iD
Author: Francis T. O’Shea
Author: Michael A. Chadwick

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