Ecohydrological modelling in a deciduous boreal forest: Model evaluation for application in non-stationary climates

TitleEcohydrological modelling in a deciduous boreal forest: Model evaluation for application in non-stationary climates
Publication TypeJournal Article
Year of Publication2021
AuthorsMarshall, AM, Link, TE, Flerchinger, GN, Nicolsky, DJ, Lucash, MS
JournalHydrological ProcessesHydrological ProcessesHydrological Processes
Volume35
Issue6
Paginatione14251
Date Published2021/06/01
ISBN Number0885-6087
Keywordsboreal, Ecohydrology, generalized likelihood uncertainty estimation, global uncertainty analysis, hydrologic model calibration, model diagnostics, soil moisture, soil temperature
Abstract

Abstract Soil moisture is an important driver of growth in boreal Alaska, but estimating soil hydraulic parameters can be challenging in this data-sparse region. Parameter estimation is further complicated in regions with rapidly warming climate, where there is a need to minimize model error dependence on interannual climate variations. To better identify soil hydraulic parameters and quantify energy and water balance and soil moisture dynamics, we applied the physically based, one-dimensional ecohydrological Simultaneous Heat and Water (SHAW) model, loosely coupled with the Geophysical Institute of Permafrost Laboratory (GIPL) model, to an upland deciduous forest stand in interior Alaska over a 13-year period. Using a Generalized Likelihood Uncertainty Estimation parameterisation, SHAW reproduced interannual and vertical spatial variability of soil moisture during a five-year validation period quite well, with root mean squared error (RMSE) of volumetric water content at 0.5 m as low as 0.020?cm3/cm3. Many parameter sets reproduced reasonable soil moisture dynamics, suggesting considerable equifinality. Model performance generally declined in the eight-year validation period, indicating some overfitting and demonstrating the importance of interannual variability in model evaluation. We compared the performance of parameter sets selected based on traditional performance measures such as the RMSE that minimize error in soil moisture simulation, with one that is designed to minimize the dependence of model error on interannual climate variability using a new diagnostic approach we call CSMP, which stands for Climate Sensitivity of Model Performance. Use of the CSMP approach moderately decreases traditional model performance but may be more suitable for climate change applications, for which it is important that model error is independent from climate variability. These findings illustrate (1) that the SHAW model, coupled with GIPL, can adequately simulate soil moisture dynamics in this boreal deciduous region, (2) the importance of interannual variability in model parameterisation, and (3) a novel objective function for parameter selection to improve applicability in non-stationary climates.

URLhttps://doi.org/10.1002/hyp.14251
Short TitleHydrological Processes