Optimizing the parameterization of deep mixing and internal seiches in one-dimensional hydrodynamic models: a case study with Simstrat v1.3

This paper presents an improvement of a one-dimensional lake hydrodynamic model (Simstrat) to characterize the vertical thermal structure of deep lakes. Using physically based arguments, we refine the transfer of wind energy to basin-scale internal waves (BSIWs). We consider the properties of the basin, the characteristics of the wind time series and the stability of the water column to filter and thereby optimize the magnitude of wind energy transferred to BSIWs. We show that this filtering procedure can significantly improve the accuracy of modelled temperatures, especially in the deep water of lakes such as Lake Geneva, for which the root mean square error between observed and simulated temperatures was reduced by up to 40 %. The modification, tested on four different lakes, increases model accuracy and contributes to a significantly better reproduction of seasonal deep convective mixing, a fundamental parameter for biogeochemical processes such as oxygen depletion. It also improves modelling over long time series for the purpose of climate change studies.

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Damien Bouffard, Adrien Gaudard, Carl Love Mikael Råman Vinnå, Martin Schmid, Robert Vincent Schwefel, Alfred Johny Wüest
Copernicus Gesellschaft Mbh, 2017
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https://infoscience.epfl.ch/record/231342?ln=en

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Application of k-epsilon turbulence models to enclosed basins: The role of internal seiches

Alfred Johny Wüest

[1] A numerical model was developed for the prediction of the density stratification of lakes and reservoirs. It combines a buoyancy-extended k-epsilon model with a seiche excitation and damping model to predict the diffusivity below the surface mixed layer. The model was applied to predict the seasonal development of temperature stratification and turbulent diffusivity in two medium-sized lakes over time periods ranging from 3 weeks to 2 years. Depending on the type of boundary condition for temperature, two or three model parameters were optimized to calibrate the model. The agreement between the simulated and the observed temperature distributions is excellent, in particular, if lake surface temperatures were prescribed as surface boundary condition instead of temperature gradients derived from heat fluxes. Comparison of different model variants revealed that inclusion of horizontal pressure gradients and/or stability functions is not required to provide good agreement between model results and data. With the aid of uncertainty analysis it is shown that the depth of the mixed surface layer during the stratified period could be predicted accurately within +/-1 m. The sensitivity of the model to several parameters is discussed.

Amer Geophysical Union2002

Resolving biogeochemical processes in lakes using remote sensing

Theo Baracchini, Damien Bouffard, Vincent Maurice Nouchi, Alfred Johny Wüest

Remote sensing helps foster our understanding of inland water processes allowing a synoptic view of water quality parameters. In the context of global monitoring of inland waters, we demonstrate the benefit of combining in-situ water analysis, hydrodynamic modelling and remote sensing for investigating biogeochemical processes. This methodology has the potential to be used at global scales. We take the example of four Landsat-8 scenes acquired by the OLI sensor and MODIS-Aqua imagery over Lake Geneva (France—Switzerland) from spring to early summer 2014. Remotely sensed data suggest a strong temporal and spatial variability during this period. We show that combining the complementary spatial, spectral and temporal resolutions of these sensors allows for a comprehensive characterization of estuarine, littoral and pelagic near-surface features. Moreover, by combining in-situ measurements, biogeochemical analysis and hydrodynamic modelling with remote sensing data, we can link these features to river intrusion and calcite precipitation processes, which regularly occur in late spring or early summer. In this context, we propose a procedure that can be used to monitor whiting events in temperate lakes worldwide.

2019

A New Sensor Platform for Investigating Turbulence in Stratified Coastal Environments

Damien Bouffard, Ulrich Lemmin

Characterizing and quantifying vertical exchange processes is essential for understanding physical and biological dynamics in stratified lakes and oceans. Unfortunately, the role of mixing is still poorly understood because of the challenges of conducting field research on small-scale turbulence, especially in the vicinity of a thermocline. This study presents a new moored sensor platform that was designed to investigate small-scale turbulence structures in time and space. The objective is to determine all terms of the turbulent energy equation separately and simultaneously. The platform is equipped with a microstructure package for measuring shear, temperature, and temperature gradients, as well as with a vertical array of high-precision thermistor probes and acoustic Doppler velocimeters. The platform can be moved vertically in the water column using a bottom-resting winch that is connected to a shore station by a 1800-m-long communication cable. This cable allows real-time data access and control of the winch, and thus optimization of the measurement strategy. A field study in Lake Geneva, located between Switzerland and France, shows that this system is ideally suited for the analysis of the dynamics of baroclinic motions, such as internal Kelvin waves. First results indicate a clear relationship between low Richardson number and elevated dissipation, and suggest a mean flux Richardson number R-f = 0.14 +/- 0.4. However, this measurement campaign was not as conclusive for the reason of the variability of R-f.

American Meteorological Society2013

Lake

A lake is a naturally occurring, relatively large body of water localized in a basin surrounded by dry land. A lake generally has a slower-moving flow than the inflow or outflow stream(s) that serve

Lake Geneva

Lake Geneva (le Léman lə lemɑ̃, lac Léman lak lemɑ̃, rarely lac de Genève lak də ʒ(ə)nɛv; Lago Lemano; Genfersee ˈɡɛnfərˌzeː; Lai da Genevra) is a deep lake on the north side of the Alps, shared bet

Great Lakes

The Great Lakes, also called the Great Lakes of North America, are a series of large interconnected freshwater lakes in the east-central interior of North America that connect to the Atlantic Ocean