Multiresponse modeling of variably saturated flow and isotope tracer transport for a hillslope experiment at the Landscape Evolution Observatory
This paper explores the challenges of model parameterization and process representation when simulating multiple hydrologic responses from a highly controlled unsaturated flow and transport experiment with a physically based model. The experiment, conducted at the Landscape Evolution Observatory...
| Main Authors: | , , , , , , , |
|---|---|
| Format: | Article |
| Language: | English |
| Published: |
Copernicus Publications
2016-10-01
|
| Series: | Hydrology and Earth System Sciences |
| Online Access: | https://www.hydrol-earth-syst-sci.net/20/4061/2016/hess-20-4061-2016.pdf |
| Summary: | This paper explores the challenges of model parameterization and process
representation when simulating multiple hydrologic responses from a highly
controlled unsaturated flow and transport experiment with a physically based
model. The experiment, conducted at the Landscape Evolution Observatory
(LEO), involved alternate injections of water and deuterium-enriched water
into an initially very dry hillslope. The multivariate observations included
point measures of water content and tracer concentration in the soil, total
storage within the hillslope, and integrated fluxes of water and tracer
through the seepage face. The simulations were performed with a
three-dimensional finite element model that solves the Richards and
advection–dispersion equations. Integrated flow, integrated transport,
distributed flow, and distributed transport responses were successively
analyzed, with parameterization choices at each step supported by standard
model performance metrics. In the first steps of our analysis, where seepage
face flow, water storage, and average concentration at the seepage face were
the target responses, an adequate match between measured and simulated
variables was obtained using a simple parameterization consistent with that
from a prior flow-only experiment at LEO. When passing to the distributed
responses, it was necessary to introduce complexity to additional soil
hydraulic parameters to obtain an adequate match for the point-scale flow
response. This also improved the match against point measures of tracer
concentration, although model performance here was considerably poorer. This
suggests that still greater complexity is needed in the model
parameterization, or that there may be gaps in process representation for
simulating solute transport phenomena in very dry soils.</p> |
|---|---|
| ISSN: | 1027-5606 1607-7938 |