Enhanced Turbulence and Energy Dissipation at Ocean Fronts

D’Asaro, Eric A.; Lee, Craig; Rainville, Luc; Harcourt, Ramsey R.; Thomas, Leif N.

doi:10.1126/science.1201515

Cited by 375 publications

(333 citation statements)

References 23 publications

Supporting

Mentioning

316

Contrasting

Order By: Relevance

“…From this characterization, it becomes clear that submesoscale processes are intensified in regions of strong lateral buoyancy gradients, strong vorticity, and weak vertical stratification. These conditions are often met in or near western boundary currents of the Pacific (D'Asaro et al 2011) and Atlantic (Thomas et al 2013;Shcherbina et al 2013), in coastal oceans, and in the Southern Ocean.…”

Section: Introductionmentioning

confidence: 99%

“…There are a number of reasons to investigate whether these features and their associated surface flow fields are sufficient to generate submesoscale variability. First, submesoscale instabilities are an efficient mechanism for generating a forward energy cascade that transfers energy from large-scale geostrophically balanced motions to smaller turbulent scales associated with dissipation (Capet et al 2008;D'Asaro et al 2011;Thomas et al 2013). SI is an example of this process.…”

Section: Introductionmentioning

confidence: 99%

“…Observations of submesoscale processes are challenging because of the constraint of capturing intermittent events that evolve rapidly on the order of 1 to 10 days. Observational programs have largely focused on regions that are preconditioned toward an active submesoscale field, for example, western boundary currents, including strong surface forcing and strong frontal gradients (D'Asaro et al 2011;Thomas et al 2013). The prevalence of these motions in more quiescent regions of the ocean remains unresolved.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Open-Ocean Submesoscale Motions: A Full Seasonal Cycle of Mixed Layer Instabilities from Gliders

Thompson

Lazar

Buckingham

et al. 2016

Journal of Physical Oceanography

164

227

View full text Add to dashboard Cite

The importance of submesoscale instabilities, particularly mixed layer baroclinic instability and symmetric instability, on upper-ocean mixing and energetics is well documented in regions of strong, persistent fronts such as the Kuroshio and the Gulf Stream. Less attention has been devoted to studying submesoscale flows in the open ocean, far from long-term, mean geostrophic fronts, characteristic of a large proportion of the global ocean. This study presents a year-long, submesoscale-resolving time series of near-surface buoyancy gradients, potential vorticity, and instability characteristics, collected by ocean gliders, that provides insight into open-ocean submesoscale dynamics over a full annual cycle. The gliders continuously sampled a 225 km 2 region in the subtropical northeast Atlantic, measuring temperature, salinity, and pressure along 292 short (;20 km) hydrographic sections. Glider observations show a seasonal cycle in near-surface stratification. Throughout the fall (September-November), the mixed layer deepens, predominantly through gravitational instability, indicating that surface cooling dominates submesoscale restratification processes. During winter (December-March), mixed layer depths are more variable, and estimates of the balanced Richardson number, which measures the relative importance of lateral and vertical buoyancy gradients, depict conditions favorable to symmetric instability. The importance of mixed layer instabilities on the restratification of the mixed layer, as compared with surface heating and cooling, shows that submesoscale processes can reverse the sign of an equivalent heat flux up to 25% of the time during winter. These results demonstrate that the openocean mixed layer hosts various forced and unforced instabilities, which become more prevalent during winter, and emphasize that accurate parameterizations of submesoscale processes are needed throughout the ocean.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Open-Ocean Submesoscale Motions: A Full Seasonal Cycle of Mixed Layer Instabilities from Gliders

Thompson

Lazar

Buckingham

et al. 2016

Journal of Physical Oceanography

164

227

View full text Add to dashboard Cite

show abstract

“…The currents enhance the air-sea interface mixing causing the transfer velocities to increase (Smith, 1999). Also, because of the enhanced turbulence and energy dissipation at ocean fronts (D'Asaro et al, 2011), there are the high transfer velocities near the polar front. Based on the same reason, there are the high transfer velocities near the Azores Current and the Azores front.…”

Section: Global Air-sea Co 2 Transfer Velocitymentioning

confidence: 99%

Global air-sea surface carbon-dioxide transfer velocity and flux estimated using ERS-2 data and a new parametric formula

Zha

et al. 2013

Acta Oceanol. Sin.

View full text Add to dashboard Cite

Using data from the European remote sensing scatterometer (ERS-2) from July 1997 to August 1998, global distributions of the air-sea CO 2 transfer velocity and flux are retrieved. A new model of the air-sea CO 2 transfer velocity with surface wind speed and wave steepness is proposed. The wave steepness (δ) is retrieved using a neural network (NN) model from ERS-2 scatterometer data, while the wind speed is directly derived by the ERS-2 scatterometer. The new model agrees well with the formulations based on the wind speed and the variation in the wind speed dependent relationships presented in many previous studies can be explained by this proposed relation with variation in wave steepness effect. Seasonally global maps of gas transfer velocity and flux are shown on the basis of the new model and the seasonal variations of the transfer velocity and flux during the 1 a period. The global mean gas transfer velocity is 30 cm/h after area-weighting and Schmidt number correction and its accuracy remains calculation with in situ data. The highest transfer velocity occurs around 60 • N and 60 • S, while the lowest on the equator. The total air to sea CO 2 flux (calculated by carbon) in that year is 1.77 Pg. The strongest source of CO 2 is in the equatorial east Pacific Ocean, while the strongest sink is in the 68 • N. Full exploration of the uncertainty of this estimate awaits further data. An effectual method is provided to calculate the effect of waves on the determination of air-sea CO 2 transfer velocity and fluxes with ERS-2 scatterometer data.

show abstract

“…Substituting relations (40) and (41) (40) into the following refined [45] semi-empirical relation (refined [45] by introducing the empirical coefficient…”

Section: Journal Of Modern Physicsmentioning

confidence: 99%

The Application of the Generalized Differential Formulation of the First Law of Thermodynamics for Evidence of the Tidal Mechanism of Maintenance of the Energy and Viscous-Thermal Dissipative Turbulent Structure of the Mesoscale Oceanic Eddies

Simonenko¹,

Лобанов²

2018

JMP

View full text Add to dashboard Cite

The practical significance of the established generalized differential formulation of the first law of thermodynamics (formulated for the rotational coordinate system) is evaluated (for the first time and for the mesoscale oceanic eddies) by deriving the general (viscous-compressible-thermal) and partial (incompressible, viscous-thermal) local conditions of the tidal maintenance of the quasi-stationary energy and dissipative turbulent structure of the mesoscale eddy located inside of the individual fluid region τ of the thermally heterogeneous viscous (compressible and incompressible, respectively) heat-conducting stratified fluid over the two-dimensional bottom topography ism of maintenance of the eddy energy and viscous-thermal dissipative structure of turbulence (produced by the breaking internal gravity waves generated by the eddy) in three regions near the Yamato Rise subjected to the observed mesoscale eddy near the northern region of the Yamato Rise of the Japan Sea.

show abstract

Enhanced Turbulence and Energy Dissipation at Ocean Fronts

Cited by 375 publications

References 23 publications

Open-Ocean Submesoscale Motions: A Full Seasonal Cycle of Mixed Layer Instabilities from Gliders

Open-Ocean Submesoscale Motions: A Full Seasonal Cycle of Mixed Layer Instabilities from Gliders

Global air-sea surface carbon-dioxide transfer velocity and flux estimated using ERS-2 data and a new parametric formula

The Application of the Generalized Differential Formulation of the First Law of Thermodynamics for Evidence of the Tidal Mechanism of Maintenance of the Energy and Viscous-Thermal Dissipative Turbulent Structure of the Mesoscale Oceanic Eddies

Contact Info

Product

Resources

About