Simulation of the Arctic &amp;ndash; North Atlantic Ocean Circulation with a Two-Equation k-omega Turbulence Parameterization

Moshonkin, S. N.; Zalesny, V. B.; Гусев, А. В.

doi:10.20944/preprints201805.0134.v1

2018

DOI: 10.20944/preprints201805.0134.v1

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Simulation of the Arctic – North Atlantic Ocean Circulation with a Two-Equation k-omega Turbulence Parameterization

S. N. Moshonkin¹,

V. B. Zalesny²,

А. В. Гусев³

Abstract: Abstract:A method for solving the turbulence equations embedded in the sigma ocean general ocean circulation model is proposed. Like the general circulation model, the turbulence equations are solved using the splitting method by physical processes. The turbulence equations are split into two main stages describing transport-diffusion and generation-dissipation processes. Parameterization of turbulence in the framework of equations allows, at the generation-dissipation stage, to use both numerical and analytic… Show more

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Cited by 7 publications

References 24 publications

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Circulation Mechanisms of the Stabilization of the Ocean Active Layer Regional Dynamics

Moshonkin

Zalesny

Гусев

et al. 2019

JOR

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Circulation patterns characterizing the variability of the dynamics of the active ocean layer describes in the regions of Greenland and Norwegian seas, in the Subpolar Gyre of the North Atlantic based on the analysis of numerical experiments for 1948–2009 with the model of the North Atlantic and the Arctic (step 0.25°, 40 levels). Density and current velocities anomalies were determined by subtracting the average annual cycle from the realizations for 0–300 m layer. Most covariant joint distributions (modes) for the spatiotemporal fields these anomalies defined by SVD analysis and investigated. An analysis of the structural, correlation, and dispersion characteristics of the main joint modes of variability of water density and current velocities anomalies is given. The second and third modes of circulation anomalies in the north of the Greenland Sea and in the Subpolar Gyre of the North Atlantic show the possibility of stabilizing the amplitude of the variability of heat and salt transport by currents and water exchange between the Atlantic and Arctic at a certain climatic level. These phenomena are characterized by the time scale from intra-monthly to six months in the north of the Greenland Sea. The change in the intensity of the anticyclonic water rotation in the Norwegian Basin balances the variability of the Atlantic Norwegian Current mass transport on a 2.5-year scale.

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Circulation Mechanisms of the Stabilization of the Ocean Active Layer Regional Dynamics

Moshonkin

Zalesny

Гусев

et al. 2019

JOR

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Reproduction of Hydrometeorological Conditions of the Kerch Strait. Part 1: Technology Verification

Фомин

Korshenko

Kabatchenko

et al. 2022

JOR

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The first part of the paper presents verification results of the technology developed at the Federal State Budgetary Institution “N. N. Zubov State Oceanographic Institute” (FSBI “SOI”) – Marine Hindcast and Forecasts System (MHFS) adapted for the Kerch Strait. It represents the complex of numerical regional models of the atmosphere, marine circulation, dynamics-thermodynamics of ice cover and wind waves for the Sea of Azov and Kerch Strait., marine circulation models of the MHFS were implemented with a high spatial resolution. This technology was used to support the design and construction of the bridge across the Kerch Strait. The capabilities of reproduction of the hydrological characteristics required for practical purposes are demonstrated by verification of model results with observational data. It is supposed to use the presented technology of calculation of hydrometeorological parameters of Kerch Strait for the monitoring system developed within the framework of the Russian Science Foundation research project 21-17-00191 “Monitoring of water exchange through the Kerch Strait on the basis of modern methods of observations and numerical modeling”. The second part will present the regime characteristics of hydrological conditions in the Kerch Strait water area.

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Mesoscale Dynamics and Eddy Heat Transport in the Japan/East Sea from 1990 to 2010: A Model-Based Analysis

Степанов

Фомин

Гусев

et al. 2021

JMSE

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The driving mechanisms of mesoscale processes and associated heat transport in the Japan/East Sea (JES) from 1990 to 2010 were examined using eddy-resolving ocean model simulations. The simulated circulation showed correctly reproduced JES major basin-scale currents and mesoscale dynamics features. We show that mesoscale eddies can deepen isotherms/isohalines up to several hundred meters and transport warm and low salinity waters along the western and eastern JES boundaries. The analysis of eddy kinetic energy (EKE) showed that the mesoscale dynamics reaches a maximum intensity in the upper 300 m layer. Throughout the year, the EKE maximum is observed in the southeastern JES, and a pronounced seasonal variability is observed in the southwestern and northwestern JES. The comparison of the EKE budget components confirmed that various mechanisms can be responsible for the generation of mesoscale dynamics during the year. From winter to spring, the baroclinic instability of basin-scale currents is the leading mechanism of the JES mesoscale dynamics’ generation. In summer, the leading role in the generation of the mesoscale dynamics is played by the barotropic instability of basin-scale currents, which are responsible for the emergence of mesoscale eddies, and in autumn, the leading role is played by instabilities and the eddy wind work. We show that the meridional heat transport (MHT) is mainly polewards. Furthermore, we reveal two paths of eddy heat transport across the Subpolar Front: along the western and eastern (along 138∘ E) JES boundaries. Near the Tsugaru Strait, we describe the detected intensive westward eddy heat transport reaching its maximum in the first half of the year and decreasing to the minimum by summer.

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Simulation of the Arctic – North Atlantic Ocean Circulation with a Two-Equation k-omega Turbulence Parameterization

Cited by 7 publications

References 24 publications

Circulation Mechanisms of the Stabilization of the Ocean Active Layer Regional Dynamics

Circulation Mechanisms of the Stabilization of the Ocean Active Layer Regional Dynamics

Reproduction of Hydrometeorological Conditions of the Kerch Strait. Part 1: Technology Verification

Mesoscale Dynamics and Eddy Heat Transport in the Japan/East Sea from 1990 to 2010: A Model-Based Analysis

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