Abstract
AbstractVertical turbulent diffusivity (Kz), which can be estimated from water temperature, is a key factor in the evolution of water quality in lentic waters. In this study, we analysed the capability of a three‐dimensional hydrodynamic model (EFDC) to capture water temperature and vertical diffusivity in Lake Arendsee in the Northern German plain. Of particular interest to us is to evaluate the model performance for capturing the diffusion minimum within the metalimnion and analyse the response of the metalimnetic Kz to meteorological forcing, namely changing wind speed and warming. The comparison confirmed that the calibrated model could reproduce both stratification dynamics and vertical diffusion profiles in the lake. The model was also shown to be able to capture the duration and vertical extent of the metalimnetic diffusion minimum. The scenario results illustrate that, compared to air temperature, wind velocity appeared to be the more influential meteorological variable on the vertical exchange within the metalimnion. While increasing wind velocities mostly affected the minimum values of Kz in the metalimnion and thus led to intensified vertical exchange, the reduction of wind velocity mostly affected the depth of minimal Kz, but not its absolute value.
Highlights
Thermal stratification is a key feature in many lentic waters such as lakes and reservoirs (Boehrer & Schultze, 2008)
We showed that the 3D model EFDC was able to simulate stratification dynamics in Lake Arendsee with high precision, resulting in an overall RMSE of only 0.78 K between modelled and observed water temperatures
We comprehensively evaluated the performance of a wellestablished 3D hydrodynamic model (EFDC) in capturing the stratification and mixing dynamics of Lake Arendsee
Summary
Thermal stratification is a key feature in many lentic waters such as lakes and reservoirs (Boehrer & Schultze, 2008). Stepanenko et al (2010) even concluded, in a comparison study of 1D lake models, that temperature dynamics below the thermocline are notoriously difficult to simulate This limitation is a consequence of the fact that turbulent kinetic energy in the hypolimnion is mostly created by the dissipation of basin scale internal waves, that is, a 3D process, and cannot be properly mimicked in a 1D approach. Our study was motivated by the question of how well a 3D hydrodynamic model is able to reproduce vertical transport beneath the surface layer, that is, within the metalimnion and the hypolimnion of a deep, stratified, temperate lake For this purpose, we chose a lake with simple basin morphometry and only marginal hydrological forcing, but with pronounced gradients and distinct physicochemical patterns along the vertical axis. Its sensitivity to the meteorological drivers (i.e. air temperature and wind velocity)
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