Hydrodynamics of a periodically wind-forced small and narrow stratified basin: a large-eddy simulation experiment

Ulloa, Hugo N.; Constantinescu, George; Chang, Keun Sick; Munoz, Daniel Horna; Steiner, Oscar Sepúlveda; Bouffard, Damien; Wüest, Alfred

doi:10.1007/s10652-018-9645-1

Cited by 12 publications

(25 citation statements)

References 78 publications

(135 reference statements)

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“…Thus, we suggest that a turbulent bottom boundary layer driven by the seiche-associated currents was the major source of mixing, dissipation, and damping of the basin-scale oscillations. In sloping bottom basins as Porce II, basin-scale circulations associated with the internal waves can accelerate the flow close to the boundaries and favor the formation of supercritical shear layers, which, in turn, induce mixing around the metalimnetic region that intersects the lake boundary (Ulloa, et al, 2018). Direct measurements of turbulent dissipation (Román-Botero, et al, 2017) also showed that during periods of dominant basin-scale internal waves activity in Porce II, there was a strongly stratified turbulence at the interior (far from the boundaries), characteristic of low dissipation, in contrast with the high-isotropic turbulence induced by the density plumes during flood events.…”

Section: Discussionmentioning

confidence: 99%

“…The natural modes are classified depending on the number of nodal points they have in the horizontal (j) and vertical (i) directions as ViHj ( Figure 1S, https://www.raccefyn.co/ index.php/raccefyn/article/downloadSuppFile/799/3895). The most commonly observed vertical baroclinic response is the V1 (Mortimer, 1953); however, higher vertical modes are not unusual (e.g., Wiegand & Chamberlain, 1987;Vidal, et al, 2005;Vidal & Casamitjana, 2007;Pannard, et al, 2011;Lorrai, et al, 2011;Ulloa, et al, 2018). The difference in the spatial structure of the modes leads to advection and mixing in different locations and, thus, it can drive mixing and turbulence at specific zones of the water column where high shear occurs (Wiegand & Chamberlain, 1987;MacIntyre, et al, 1999;Hondzo & Haider, 2005;Henderson, 2016).…”

Section: Introductionmentioning

confidence: 99%

“…The difference in the spatial structure of the modes leads to advection and mixing in different locations and, thus, it can drive mixing and turbulence at specific zones of the water column where high shear occurs (Wiegand & Chamberlain, 1987;MacIntyre, et al, 1999;Hondzo & Haider, 2005;Henderson, 2016). The vertical structure of the oscillations can influence the circulation patterns in the lake (Vidal, et al, 2005;Vidal, et al, 2007;Ulloa, et al, 2018) and affect the properties of the water withdrawn for the reservoir operation (Anohin, et al, 2006), as well as the routes followed by substances and species entering to the reservoir from the inflow discharges (Cortés, et al, 2014;Hogg, et al, 2018). Vertical one modes typically lead to stronger dissipation around the basin perimeter through the turbulent boundary layer, while higher order vertical modes tend to dissipate more of its energy through increased shear at the interior of the lake (Simpson, et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

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Preliminary characterization of the dominant baroclinic modes of a tropical Andean reservoir during a dry period

Posada-Bedoya

Gómez-Giraldo

Román-Botero

2019

Rev. Acad. Colomb. Cienc. Ex. Fis. Nat.

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A partir de datos de campo y un modelo numérico simple, se investigaron las ondas internas escala de cuenco en un embalse tropical andino durante un período seco. La estructura y el período de las oscilaciones baroclínicas observadas, se infirieron a partir del análisis espectral de las series de temperatura medidas y de los desplazamientos verticales de las isotermas asociadas. El modo de oscilación dominante identificado a partir de los datos de campo constaba de dos capas que oscilaban con velocidades verticales y fases contrarias (modo V2), y con un período de 24 h. Los modos baroclínicos verticales teóricos del embalse se estimaron a partir de un eigenmodelo simple, el cual predijo el período y la estructura vertical del modo dominante identificado a partir de las observaciones, indicando también que las oscilaciones de la velocidad horizontal en cada capa estaban en fase (modo V2H1) y con un período natural cercano a 24 h. El forzamiento del viento mostró una variabilidad periódica con un período dominante cercano a las 24 h, por lo que concluimos que el modo V2H1 fue el dominante durante el período analizado y sometido a excitación por resonancia con el forzamiento diurno del viento. Se modeló el embalse como un sistema lineal masa-resorte, amortiguado y forzado, con el fin de estimar la relación de amortiguamiento de las oscilaciones baroclínicas, y se obtuvieron oscilaciones subamortiguadas con una tasa de amortiguamiento similar a la reportada en otros lagos alrededor del mundo. También se investigó el potencial del modo V2H1 en la generación vertical de turbulencia debido a inestabilidades cortantes usando el número de Richardson del gradiente, y encontramos que la producción de turbulencia era baja. Por último, se discuten aquí la estructura vertical de la fase en las oscilaciones de las ondas internas y las potenciales implicaciones del campo de ondas internas en la ecología del embalse. © 2019. Acad. Colomb. Cienc. Ex. Fis. Nat.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Preliminary characterization of the dominant baroclinic modes of a tropical Andean reservoir during a dry period

Posada-Bedoya

Gómez-Giraldo

Román-Botero

2019

Rev. Acad. Colomb. Cienc. Ex. Fis. Nat.

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“…Seiches cause a wide spectrum of temporal fluctuations of all thermodynamic, hydrodynamic, and biogeochemical quantities in lakes, with maximal magnitudes in thermocline and profound secondary circulations at shores (Ulloa et al, 2019). A large number of models has been developed (e.g., Horn et al, 1986;Kirillin et al, 2015;Lemmin et al, 2005;Rueda & Schladow, 2002) specifically for simulation of seiche currents, based on both layer-wise and continuous representation of vertical density stratification.…”

Section: Introductionmentioning

confidence: 99%

“…Typically those models have not been coupled to turbulence closures and thermodynamic models, in order to represent effect of seiches on vertical mixing. Hence, so far two branches of lake modeling have been developing almost independently, namely, 1-D thermodynamic models and internal wave models (in this paper we do not discuss fully 3-D lake models (e.g., Delandmeter et al, 2018;Laval et al, 2003;Tsvetova, 1999;Ulloa et al, 2019) that explicitly reproduce wide range of circulation modes and interaction between hydrodynamic and thermodynamic variables). This paper strives to develop a computationally cheap extension to 1-D k − model, explicitly reproducing dominant seiche modes in momentum equations.…”

Section: Introductionmentioning

confidence: 99%

Horizontal Pressure Gradient Parameterization for One‐Dimensional Lake Models

Stepanenko

Valerio

Pilotti

2020

J Adv Model Earth Syst

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This work presents a new method for closure of horizontally averaged 1‐D thermohydrodynamic equations in an enclosed reservoir by parameterizing the horizontal pressure gradient usually omitted in 1‐D lake models. Horizontal pressure gradient is computed using an auxiliary multilayer model where horizontal structure of speed and pressure is given by 1‐st Fourier mode. A major effect of new parameterization in 1‐D lake model is the emergence of explicitly reproduced H1 seiche modes. The parameterization is implemented in the LAKE model, with minor (2–4%) extra computational cost imposed. The model is applied to Lake Iseo (Italy), and calculated temperature series are compared to measured ones in upper, middle, and deep portions of metalimnion. The amplitude of seiche‐induced temperature oscillations well matched the observed amplitude by tuning the bottom friction coefficient only. The synoptic variability of thermocline vertical displacement caused by wind events is well reproduced by the model. The dominant peak of quasi‐diurnal period in temperature power spectrum was captured in simulations as well. Using the new parameterization of horizontal pressure gradient extends the applicability of a 1‐D lake model formulation to small lakes, which size is less than internal Rossby radius, and where pressure gradient dominates over Coriolis force.

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Periodic boundary layer separation and lateral intrusions observed above a sloping lakebed

Nielson

Henderson

2022

Limnology & Oceanography

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Lateral intrusions flowing from the boundaries of lakes and oceans might influence basin-scale distributions of heat, chemical solutes, sediments, and organisms. Here, observations of numerous intrusions from multiple locations in a small lake were used to examine the relation of intrusions to a lakewide internal seiche, and to estimate mean exchange between sloping bottom boundary layers (BBLs) and the lake interior. BBL waters were observed periodically separating from the bed and flowing laterally offshore. Boundary layer separation was initiated where strong downslope flows encountered upslope-propagating temperature fronts. These separation events propagated upslope, coherent with the vertically propagating internal seiche, resembling previously reported cases of upslope-propagating internal bores. Following separation, jets flowed offshore immediately above temperature fronts, transporting boundary layer water at least 61 m into the interior. Jet propagation could be traced upwards, from the bed at 9.4 m depth to the base of the surface mixed layer. Mean offshore transport was most intense within the metalimnion (4-7 m depth). Intruding intermediate-temperature thermocline water was likely supplied both by river inputs and by boundary mixing of cold and warm waters. These findings suggest that periodic jets, resulting from seiche-induced boundary layer separation, transported significant quantities of water from the boundary layer toward the stratified lake interior, with possible implications for distributions of sediments, solutes, and organisms.

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Hydrodynamics of a periodically wind-forced small and narrow stratified basin: a large-eddy simulation experiment

Abstract: Ulloa et al.

Cited by 12 publications

References 78 publications

Preliminary characterization of the dominant baroclinic modes of a tropical Andean reservoir during a dry period

Preliminary characterization of the dominant baroclinic modes of a tropical Andean reservoir during a dry period

Horizontal Pressure Gradient Parameterization for One‐Dimensional Lake Models

Periodic boundary layer separation and lateral intrusions observed above a sloping lakebed

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