Modeling Lobe-And-Cleft Instabilities on a River Plume

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Author(s)Shi, Fengyan
Author(s)Simpson, Alexandra
Author(s)Hsu, Tian-Jian
Date Accessioned2024-07-01T19:54:05Z
Date Available2024-07-01T19:54:05Z
Publication Date2024-05-13
DescriptionThis article was originally published in Journal of Geophysical Research: Oceans by AGU. Published 2024 American Geophysical Union. Shi, F., Simpson, A., & Hsu, T.‐J. (2024).Modeling lobe‐and‐cleft instabilities on ariver plume. Journal of Geophysical Research: Oceans, 129, e2023JC020485. To view the published open abstract, go to https://doi.org/10.1029/2023JC020485. © 2024. American Geophysical Union. All Rights Reserved. This article will be embargoed until 11/13/2024.
AbstractAbstract The lobe-and-cleft instability is a widely recognized mechanism leading to along-front structure on density current fronts. Early studies based on laboratory and numerical simulations suggested that the lobe-and-cleft instability is due to convective instability in the nose of gravity currents traveling over a nonslip boundary. Horner-Devine and Chickadel (2017, https://doi.org/10.1002/2017gl072997) reported the presence of lobe-and-cleft instabilities at the Merrimack River, which are generated at the river front in the absence of a no-slip boundary. Hence, the observed lobe-and-cleft instabilities must be due to other mechanisms. In this study, we carried out non-hydrostatic large eddy simulations of a riverine outflow into an idealized 3D domain. With a fine grid resolution of 0.15 × 0.31 m in two horizontal directions and about 0.125 m in the vertical direction, the model reproduced the lobe-and-cleft feature, with the magnitude and size of lobes consistent with the field observation. The model results revealed that instabilities start from the primary Kelvin-Helmholtz instability, followed by the secondary instability through stretching and tilting, generating counter-rotating streamwise vortices in the plume and at the plume head. The upwelling associated with streamwise vortex cells brings a slower flow to the plume surface, resulting in lobe-and-cleft patterns at the front and positive and negative vertical vorticity at the plume surface. The model also predicted a lobe width of about two to three times the plume thickness, consistent with the field observation and the lobe/cleft spacing associated with pairs of counter-rotating streamwise vortices. Modeled turbulent dissipation rate shows a trend of exponential decay from 10−4 to 10−3 m2/s3 at the frontal head to 10−7 to 10−6 m2/s3 behind the front, similar to the findings in the previous field studies. Key Points A non-hydrostatic large eddy simulation model is applied to reproduce lobe-and-cleft instabilities observed at the Merrimack River Model results reveal that instabilities originate from the Kelvin-Helmholtz instability, followed by the secondary instability, generating counter-rotating streamwise vortices at the front Modeled turbulent dissipation rate shows an exponential decay with increasing distance away from the front, consistent with field measurements Plain Language Summary Density currents are ubiquitous in nature and they play a key role in many important processes, such as weather pattern, ocean temperature and ecosystem, and sediment transport. The lobe-and-cleft instability is a mechanism that leads to along-front structure on density current fronts. These instabilities are prominent features for identifying the existence of density currents and they are also responsible for kinetic energy dissipation and mixing associated with the density currents. Although lobe-and-cleft instabilities have been observed in river plume fronts, their generation mechanisms remain unclear. In this study, we used a computer model to simulate the phenomena in an idealized domain similar to field observation. The model was able to reproduce the lobe-and-cleft feature that was observed in the field. We found that the instabilities were initiated from the primary Kelvin-Helmholtz instability and were followed by the secondary instability through stretching and tilting. This generates contour-rotating streamwise vortices in the plume and extends to the plume head. The lobe-and-clefts feature is caused by the upwelling associated with these streamwise vortex cells, which bring a slower flow to the plume surface.
SponsorThis research was funded through the following grants from the Office of Naval Research: N000141612854 and N000141712796. The authors especially thank Merrick Haller, Rocky Geyer, James T. Kirby, Joe Jurisa, and David Honegger for insightful discussions, feedback, and encouragement on this work. The authors wish to thank Dr. Horner-Devine and an anonymous reviewer for their constructive comments and suggestions. Numerical simulations were carried out on the DoD HPCMP system and the DARWIN HPC system at the University of Delaware.
CitationShi, F., Simpson, A., & Hsu, T.-J. (2024). Modeling lobe-and-cleft instabilities on a river plume. Journal of Geophysical Research: Oceans, 129, e2023JC020485. https://doi.org/10.1029/2023JC020485
ISSN2169-9291
URLhttps://udspace.udel.edu/handle/19716/34550
Languageen_US
PublisherJournal of Geophysical Research: Oceans
TitleModeling Lobe-And-Cleft Instabilities on a River Plume
TypeArticle
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