Abstract
We developed an on-line coupling between the 1D/quasi-2D nutrient
transport model ANIMO and the 3D groundwater transport model code
MT3DMS. ANIMO is a detailed, process-oriented model code for the
simulation of nitrate leaching to groundwater, N- and P-loads on surface
waters and emissions of greenhouse gasses. It is the leading nutrient
fate and transport code in the Netherlands where it is used primarily
for the evaluation of fertilization related legislation. In addition,
the code is applied frequently in international research projects.
MT3DMS is probably the most commonly used groundwater solute transport
package worldwide. The on-line model coupling ANIMO-MT3DMS combines the
state-of-the-art descriptions of the biogeochemical cycles in ANIMO with
the advantages of using a 3D approach for the transport through the
saturated domain. These advantages include accounting for regional
lateral transport, considering groundwater-surface water interactions
more explicitly, and the possibility of using MODFLOW to obtain the flow
fields. An additional merit of the on-line coupling concept is that it
preserves feedbacks between the saturated and unsaturated zone. We
tested ANIMO-MT3DMS by simulating nutrient transport for the period
1970-2007 in a Dutch agricultural polder catchment covering an area of
118 km2. The transient groundwater flow field had a temporal resolution
of one day and was calculated with MODFLOW-MetaSWAP. The horizontal
resolution of the model grid was 100x100m and consisted of 25 layers of
varying thickness. To keep computation times manageable, we prepared
MT3DMS for parallel computing, which in itself is a relevant development
for a large community of groundwater transport modelers. For the
parameterization of the soil, we applied a standard classification
approach, representing the area by 60 units with unique combinations of
soil type, land use and geohydrological setting. For the geochemical
parameterization of the deeper subsurface, however, we applied a novel
geostatistical technique, which allocates reactivity parameters to the
grid cells by sampling from these parameters' cumulative frequency
distribution (CDF) functions. These CDF functions are derived for each
relevant geohydrological unit present in the model domain, from datasets
of groundwater and sediment analyses. The nutrient loads on the surface
water system and the nutrient concentrations in groundwater, simulated
by the transport model, are in fair agreement with field measurements.
The experience with the test model constitutes a proof-of-concept,
justifying further developments towards application of ANIMO-MT3DMS in
actual regional decision-making processes.
Original language | English |
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Publication status | Published - 2012 |
Event | American Geophysical Union Fall Meeting 2012 - San Francisco, USA Duration: 3 Dec 2012 → 7 Dec 2012 |
Conference
Conference | American Geophysical Union Fall Meeting 2012 |
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City | San Francisco, USA |
Period | 3/12/12 → 7/12/12 |
Keywords
- [1804] HYDROLOGY / Catchment
- [1831] HYDROLOGY / Groundwater quality
- [1832] HYDROLOGY / Groundwater transport
- [1847] HYDROLOGY / Modeling