Influence of tides and waves on the fate of nutrients in a nearshore aquifer: Numerical simulations
•Tides and waves alter land-derived nutrient discharge pathways and transformations.•Nutrient fate is strongly controlled by inputs of marine-derived constituents.•Fate of land-derived nutrients depends on redox conditions in mixing zones.•Simulated nutrient regeneration from DOM degradation not con...
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| Published in | Advances in water resources Vol. 73; pp. 203 - 213 |
|---|---|
| Main Authors | , , |
| Format | Journal Article |
| Language | English |
| Published |
Kidlington
Elsevier Ltd
01.11.2014
Elsevier |
| Subjects | |
| Online Access | Get full text |
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| Abstract | •Tides and waves alter land-derived nutrient discharge pathways and transformations.•Nutrient fate is strongly controlled by inputs of marine-derived constituents.•Fate of land-derived nutrients depends on redox conditions in mixing zones.•Simulated nutrient regeneration from DOM degradation not controlled by mixing.
A numerical investigation is presented that demonstrates the influence of tides and waves on the transport and transformation of nutrients (NO3-,NH4+,PO43-) in a homogeneous unconfined nearshore aquifer and subsequent fluxes to the sea. Simulations of an aquifer subject to semi-diurnal tides and constant waves acting on a sloping beach face were conducted using SEAWAT-2005 combined with PHT3D v2.10. Tidal amplitude (A) and wave height (Hrms) varying from 0.25 to 0.75m and 1 to 2m, respectively, were examined. Results show that tides and waves modify the subsurface discharge pathway of land-derived nutrients by changing the nearshore groundwater flow dynamics. More importantly, the oceanic forcing impacts nutrient cycling as it causes significant seawater exchange (along with dissolved O2 and organic matter) across the aquifer-ocean interface. Although steady wave forcing caused higher seawater influx, tides led to greater seawater-freshwater mixing in the nearshore aquifer and subsequently greater transformation of land-derived nutrients. Nutrient processing was strongly controlled by the availability and reactivity of marine dissolved organic matter (DOM) as its degradation consumed O2, released inorganic N and P, and altered redox conditions in the salt-freshwater mixing zones. For the conditions and reaction network simulated, nutrient regeneration by marine DOM degradation was independent of the seawater-freshwater mixing intensity, and therefore was greatest for the wave case due to the high seawater influx. For simulations without marine DOM considered, NO3- discharge to the sea increased by 32% for the tidal case (A=0.5m) compared to only 13% and 8% for the wave (Hrms=1m) and no oceanic forcing cases. With labile marine DOM considered, the NO3- discharge decreased by 90% relative to the land-derived flux for the tidal case (A=0.5m). For all simulations PO43-removal was high due to its adsorption to Fe oxide minerals. The model enables evaluation of the complex coupled physical-biogeochemical processes controlling nutrient loading to the sea via submarine groundwater discharge in dynamic coastal environments. |
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| AbstractList | A numerical investigation is presented that demonstrates the influence of tides and waves on the transport and transformation of nutrients () in a homogeneous unconfined nearshore aquifer and subsequent fluxes to the sea. Simulations of an aquifer subject to semi-diurnal tides and constant waves acting on a sloping beach face were conducted using SEAWAT-2005 combined with PHT3D v2.10. Tidal amplitude () and wave height () varying from 0.25 to 0.75m and 1 to 2m, respectively, were examined. Results show that tides and waves modify the subsurface discharge pathway of land-derived nutrients by changing the nearshore groundwater flow dynamics. More importantly, the oceanic forcing impacts nutrient cycling as it causes significant seawater exchange (along with dissolved and organic matter) across the aquifer-ocean interface. Although steady wave forcing caused higher seawater influx, tides led to greater seawater-freshwater mixing in the nearshore aquifer and subsequently greater transformation of land-derived nutrients. Nutrient processing was strongly controlled by the availability and reactivity of marine dissolved organic matter (DOM) as its degradation consumed O2, released inorganic N and P, and altered redox conditions in the salt-freshwater mixing zones. For the conditions and reaction network simulated, nutrient regeneration by marine DOM degradation was independent of the seawater-freshwater mixing intensity, and therefore was greatest for the wave case due to the high seawater influx. For simulations without marine DOM considered, discharge to the sea increased by 32% for the tidal case (A =0.5m) compared to only 13% and 8% for the wave ( =1m) and no oceanic forcing cases. With labile marine DOM considered, the discharge decreased by 90% relative to the land-derived flux for the tidal case (A =0.5m). For all simulations removal was high due to its adsorption to Fe oxide minerals. The model enables evaluation of the complex coupled physical-biogeochemical processes controlling nutrient loading to the sea via submarine groundwater discharge in dynamic coastal environments. •Tides and waves alter land-derived nutrient discharge pathways and transformations.•Nutrient fate is strongly controlled by inputs of marine-derived constituents.•Fate of land-derived nutrients depends on redox conditions in mixing zones.•Simulated nutrient regeneration from DOM degradation not controlled by mixing. A numerical investigation is presented that demonstrates the influence of tides and waves on the transport and transformation of nutrients (NO3-,NH4+,PO43-) in a homogeneous unconfined nearshore aquifer and subsequent fluxes to the sea. Simulations of an aquifer subject to semi-diurnal tides and constant waves acting on a sloping beach face were conducted using SEAWAT-2005 combined with PHT3D v2.10. Tidal amplitude (A) and wave height (Hrms) varying from 0.25 to 0.75m and 1 to 2m, respectively, were examined. Results show that tides and waves modify the subsurface discharge pathway of land-derived nutrients by changing the nearshore groundwater flow dynamics. More importantly, the oceanic forcing impacts nutrient cycling as it causes significant seawater exchange (along with dissolved O2 and organic matter) across the aquifer-ocean interface. Although steady wave forcing caused higher seawater influx, tides led to greater seawater-freshwater mixing in the nearshore aquifer and subsequently greater transformation of land-derived nutrients. Nutrient processing was strongly controlled by the availability and reactivity of marine dissolved organic matter (DOM) as its degradation consumed O2, released inorganic N and P, and altered redox conditions in the salt-freshwater mixing zones. For the conditions and reaction network simulated, nutrient regeneration by marine DOM degradation was independent of the seawater-freshwater mixing intensity, and therefore was greatest for the wave case due to the high seawater influx. For simulations without marine DOM considered, NO3- discharge to the sea increased by 32% for the tidal case (A=0.5m) compared to only 13% and 8% for the wave (Hrms=1m) and no oceanic forcing cases. With labile marine DOM considered, the NO3- discharge decreased by 90% relative to the land-derived flux for the tidal case (A=0.5m). For all simulations PO43-removal was high due to its adsorption to Fe oxide minerals. The model enables evaluation of the complex coupled physical-biogeochemical processes controlling nutrient loading to the sea via submarine groundwater discharge in dynamic coastal environments. A numerical investigation is presented that demonstrates the influence of tides and waves on the transport and transformation of nutrients (NO3-,NH4+,PO43-) in a homogeneous unconfined nearshore aquifer and subsequent fluxes to the sea. Simulations of an aquifer subject to semi-diurnal tides and constant waves acting on a sloping beach face were conducted using SEAWAT-2005 combined with PHT3D v2.10. Tidal amplitude (A) and wave height (Hrms) varying from 0.25 to 0.75m and 1 to 2m, respectively, were examined. Results show that tides and waves modify the subsurface discharge pathway of land-derived nutrients by changing the nearshore groundwater flow dynamics. More importantly, the oceanic forcing impacts nutrient cycling as it causes significant seawater exchange (along with dissolved O2 and organic matter) across the aquifer-ocean interface. Although steady wave forcing caused higher seawater influx, tides led to greater seawater-freshwater mixing in the nearshore aquifer and subsequently greater transformation of land-derived nutrients. Nutrient processing was strongly controlled by the availability and reactivity of marine dissolved organic matter (DOM) as its degradation consumed O2, released inorganic N and P, and altered redox conditions in the salt-freshwater mixing zones. For the conditions and reaction network simulated, nutrient regeneration by marine DOM degradation was independent of the seawater-freshwater mixing intensity, and therefore was greatest for the wave case due to the high seawater influx. For simulations without marine DOM considered, NO3- discharge to the sea increased by 32% for the tidal case (A=0.5m) compared to only 13% and 8% for the wave (Hrms=1m) and no oceanic forcing cases. With labile marine DOM considered, the NO3- discharge decreased by 90% relative to the land-derived flux for the tidal case (A=0.5m). For all simulations PO43-removal was high due to its adsorption to Fe oxide minerals. The model enables evaluation of the complex coupled physical-biogeochemical processes controlling nutrient loading to the sea via submarine groundwater discharge in dynamic coastal environments. |
| Author | Barry, D.A. Robinson, C. Anwar, N. |
| Author_xml | – sequence: 1 givenname: N. surname: Anwar fullname: Anwar, N. email: nirwan_010@yahoo.com organization: Department of Civil and Environmental Engineering, Western University, London N5X 4R5, ON, Canada – sequence: 2 givenname: C. surname: Robinson fullname: Robinson, C. email: crobinson@eng.uwo.ca organization: Department of Civil and Environmental Engineering, Western University, London N5X 4R5, ON, Canada – sequence: 3 givenname: D.A. surname: Barry fullname: Barry, D.A. email: andrew.barry@epfl.ch organization: Laboratoire de technologie écologique, Institut d’ingénierie de l’environnement, Faculté de l’environnement naturel, architectural et construit (ENAC), Station 2, Ecole Polytechnique Fédérale de Lausanne (EPFL), 1015 Lausanne, Switzerland |
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| Keywords | Phosphorous Nitrogen Submarine groundwater discharge Subterranean estuary Reactive transport model Oceanic forcing oxides submarine springs mixing ground water degradation digital simulation nitrates ammonium ion nutrients beaches aquifers discharge flow sea water models adsorption interfaces salt transport chemically precipitated rocks evaporites tides coastal environment sedimentary rocks phosphates water resource management organic materials |
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| Snippet | •Tides and waves alter land-derived nutrient discharge pathways and transformations.•Nutrient fate is strongly controlled by inputs of marine-derived... A numerical investigation is presented that demonstrates the influence of tides and waves on the transport and transformation of nutrients () in a homogeneous... A numerical investigation is presented that demonstrates the influence of tides and waves on the transport and transformation of nutrients (NO3-,NH4+,PO43-) in... |
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| SubjectTerms | adsorption Aquifers beaches biogeochemical cycles Computer simulation Discharge dissolved organic matter dissolved oxygen Earth sciences Earth, ocean, space Engineering and environment geology. Geothermics Exact sciences and technology groundwater groundwater flow Hydrogeology Hydrology. Hydrogeology iron oxides Marine mathematical models mixing nitrates Nitrogen Nutrients Oceanic forcing oxygen oxygen consumption Phosphorous pollution load Pollution, environment geology Reactive transport model Sea water seawater Simulation Submarine groundwater discharge Subterranean estuary Tides Water resources |
| Title | Influence of tides and waves on the fate of nutrients in a nearshore aquifer: Numerical simulations |
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