2014
DOI: 10.1002/2014jc010396
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Stratified turbulence in the nearshore coastal ocean: Dynamics and evolution in the presence of internal bores

Abstract: High-frequency measurements of stratified turbulence throughout the water column were collected over a 2 week period in the nearshore environment of southern Monterey Bay, CA, using a cabled observatory system and an underwater turbulence flux tower. The tower contained a vertical array of acoustic Doppler velocimeters and fast-response conductivity-temperature sensors, providing a nearly continuous data set of turbulent velocity and density fluctuations and a unique look into the stratified turbulence field. … Show more

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Cited by 63 publications
(73 citation statements)
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References 72 publications
(212 reference statements)
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“…Among a number of nondimensional parameters that have been identified as potentially relevant for the determination of γ in shear‐driven turbulence is the buoyancy Reynolds number, Reb=ενN2 , which can be interpreted as a measure of the ratio of the Ozmidov scale LO=false(ε/N3false)1/2 and the Kolmogorov scale η=false(ν3/εfalse)1/4. Available data suggest that in the “energetic regime” with Reb>100, the flux coefficient follows a power‐law relationship of the form γ=aReb12 for Reb>100 , where a is a model parameter that is presently not well constrained [ Shih et al ., ; Walter et al ., ]. Based on their analysis of a large number of data, Bouffard and Boegman [] suggest that the best fit is provided by a = 2, which corresponds to the value originally proposed by Shih et al .…”
Section: Discussionsupporting
confidence: 77%
See 1 more Smart Citation
“…Among a number of nondimensional parameters that have been identified as potentially relevant for the determination of γ in shear‐driven turbulence is the buoyancy Reynolds number, Reb=ενN2 , which can be interpreted as a measure of the ratio of the Ozmidov scale LO=false(ε/N3false)1/2 and the Kolmogorov scale η=false(ν3/εfalse)1/4. Available data suggest that in the “energetic regime” with Reb>100, the flux coefficient follows a power‐law relationship of the form γ=aReb12 for Reb>100 , where a is a model parameter that is presently not well constrained [ Shih et al ., ; Walter et al ., ]. Based on their analysis of a large number of data, Bouffard and Boegman [] suggest that the best fit is provided by a = 2, which corresponds to the value originally proposed by Shih et al .…”
Section: Discussionsupporting
confidence: 77%
“…The computation of the mixing rate Ep from (8) is complicated by the potential variability of the flux coefficient γ . The use of the canonical value γ=0.2 to describe BBL mixing is inconsistent with an increasing body of observational evidence suggesting a significant reduction of γ in energetic turbulent flows, e.g., in shallow coastal areas or in the energetic near‐bottom region [e.g., Walter et al ., ; Bluteau et al ., ; Davis and Monismith , ]. Among a number of nondimensional parameters that have been identified as potentially relevant for the determination of γ in shear‐driven turbulence is the buoyancy Reynolds number, Reb=ενN2 , which can be interpreted as a measure of the ratio of the Ozmidov scale LO=false(ε/N3false)1/2 and the Kolmogorov scale η=false(ν3/εfalse)1/4.…”
Section: Discussionmentioning
confidence: 99%
“…Within the thermocline, the intensity of diapycnal mixing generated by the observed values of dissipation of turbulent kinetic energy is estimated by using the Osborn relation for every ɛ estimate: Kρ=ΓɛN2, where Γ is the so called “mixing efficiency.” Γ has been frequently set to 0.2 for shear‐generated mixing (Osborn, ; Thorpe, ), although more recent studies reporting on direct numerical simulations (Shih et al, ) and oceanic field measurements (Walter et al, ) define Γ=f(IA).…”
Section: Resultsmentioning
confidence: 99%
“…It is worth noting that the present buoyancy Reynolds numbers [Re b 5 «/(nN (Shih et al 2005;Davis and Monismith 2011;Dunckley et al 2012;Bouffard et al 2013;Walter et al 2014). Our observations may thus highlight a specific case of efficient mixing that occurs during internal wave breaking on deep sloping topography, when the breaking is associated with high available potential energy.…”
Section: On the Apparent Mixing Efficiency Of Turbulence Above Slopinmentioning
confidence: 93%
“…These difficulties lie in the fact that turbulence is generally intermittent (the stationary hypothesis needed to compute G does not hold) and that separating reversible and nonreversible density fluctuations is complex, making any estimation of J b difficult (Bouffard et al 2013). This question was addressed in numerical (Slinn andRiley 1996, 1998;Umlauf and Burchard 2011;Mashayek and Peltier 2013) and laboratory studies (Ivey and Nokes 1989) but also from in situ measurements (van Haren et al 1994;Davis and Monismith 2011;Dunckley et al 2012;Walter et al 2014).…”
Section: On the Apparent Mixing Efficiency Of Turbulence Above Slopinmentioning
confidence: 99%