Turbulence and high-frequency variability in a deep gravity current outflow

Jonathan D. Nash; Hartmut Peters; Samuel M. Kelly; Josep L. Pelegrí; Mikhail Emelianov; Marc Gasser

doi:10.1029/2012GL052899

Turbulence and high-frequency variability in a deep gravity current outflow

Jonathan D. Nash, Hartmut Peters, Samuel M. Kelly, Josep L. Pelegrí, Mikhail Emelianov, Marc Gasser

Physics & Astronomy (Duluth)

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15 Scopus citations

Abstract

Intensive sampling of the deep Mediterranean outflow 70 km W of the Strait of Gibraltar reveals a strong, tidally modulated gravity current embedded with large-amplitude oscillations and energetic turbulence. The flow appears to be hydraulically controlled at a small topographic constriction, with turbulence and internal waves varying together and increasing dramatically downstream of the choke point. These data suggest that a significant fraction of energy dissipation, mixing, and entrainment stress in gravity currents may occur in localized regions controlled by time-varying flow interactions with fine-scale topography. These findings highlight the important role of processes that are not resolved by global climate models (GCMs), which do not contain tides or mixing due to fine-scale topographic interactions.

Original language	English (US)
Article number	L18611
Journal	Geophysical Research Letters
Volume	39
Issue number	17
DOIs	https://doi.org/10.1029/2012GL052899
State	Published - Sep 1 2012

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abstract = "Intensive sampling of the deep Mediterranean outflow 70 km W of the Strait of Gibraltar reveals a strong, tidally modulated gravity current embedded with large-amplitude oscillations and energetic turbulence. The flow appears to be hydraulically controlled at a small topographic constriction, with turbulence and internal waves varying together and increasing dramatically downstream of the choke point. These data suggest that a significant fraction of energy dissipation, mixing, and entrainment stress in gravity currents may occur in localized regions controlled by time-varying flow interactions with fine-scale topography. These findings highlight the important role of processes that are not resolved by global climate models (GCMs), which do not contain tides or mixing due to fine-scale topographic interactions.",

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AU - Nash, Jonathan D.

AU - Peters, Hartmut

AU - Kelly, Samuel M.

AU - Pelegrí, Josep L.

AU - Emelianov, Mikhail

AU - Gasser, Marc

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Turbulence and high-frequency variability in a deep gravity current outflow

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