Generation of Vertical Fine Structure by the Internal Waves with the Regard for Turbulent Viscosity and Diffusion

A. A. Slepyshev, A. V. Nosova

Marine Hydrophysical Institute, Russian Academy of Sciences, Sevastopol, Russian Federation

e-mail: slep55@mail.ru

Abstract

Purpose. The aim is to study the mechanism of formation of a vertical fine structure due to the mass vertical transfer by the internal waves taking into account turbulent viscosity and diffusion as well as to investigate influence of the critical layers on the dispersion curves of internal waves.

Methods and Results. In the Boussinesq approximation, the free inertia-gravity internal waves in a vertically inhomogeneous flow are considered with the regard for the horizontal turbulent viscosity and diffusion. The equation for the amplitude of vertical velocity of the internal waves contains a small parameter (in the dimensionless variables) proportional to the value of the horizontal turbulent viscosity. The solution of this equation is realized in a form of the asymptotic series of this parameter. In the zero approximation, the second-order homogeneous boundary value problem determined the vertical structure mode is solved numerically by the implicit third-order accuracy Adams scheme for real profiles of the Brent-Väisälä frequency and the current velocity. At the fixed wave frequency, the wave number is determined by the shooting method. In the first order with respect to the indicated parameter, the semi-homogeneous boundary value problem is also solved numerically according to the implicit Adams scheme of the third order of accuracy. A unique solution is found which is orthogonal to the solution of the corresponding homogeneous boundary value problem. The condition of this boundary value problem solvability yields the wave attenuation decrement. The dispersion curves of the first two modes are cut off in the low-frequency region (the second mode is at a higher frequency), that is due to influence of the critical layers, where the wave frequency with the Doppler shift is inertial. It is shown that the mass vertical wave flux differs from zero and leads to correction (not oscillating on the wave time scale) of the average density, i. e. the internal wave generate fine structure that is of an irreversible character.

Conclusions. When the horizontal turbulent viscosity and diffusion are taken into consideration, the mass vertical wave flux differs from zero and leads to generation of the vertical fine structure. The mass wave flux exceeds the turbulent one. The vertical scales of the generated vertical fine structure correspond to the actually observed ones.

Keywords

internal waves, wave flux of mass, fine structure, critical layers

Acknowledgements

The investigation was carried out within the framework of the state task on theme No. 0827-2018-0003 “Fundamental studies of oceanic processes determined state and evolution of marine environment being affected by natural and anthropogenic factors, based on observation and modeling methods”.

Original russian text

Original Russian Text © A.A. Slepyshev, A.V. Nosova, 2020, published in MORSKOY GIDROFIZICHESKIY ZHURNAL, Vol. 36, Iss. 1, pp. 5–19 (2020)

For citation

Slepyshev, A.A. and Nosova, A.V., 2020. Generation of Vertical Fine Structure by the Internal Waves with the Regard for Turbulent Viscosity and Diffusion. Physical Oceanography, 27(1), pp. 3-17. doi:10.22449/1573-160X-2020-1-3-17

DOI

10.22449/1573-160X-2020-1-3-17

References

  1. Dykman, V.Z., 2016. Technical Tools for Studying Structure and Dynamics of Water Masses. Physical Oceanography, (6), pp. 49-62. doi:10.22449/1573-160X-2016-6-43-55
  2. Sabinin, K.D. and Serebryanyi, A.N., 2012. Results of Using Acoustic Doppler Current Profilers for Studying the Spatial Structure of the Marine Environment. Acoustical Physics, 58(5), pp. 586-595. https://doi.org/10.1134/S106377101203013X
  3. Paka, V.T., Rudels, B., Quadfasel, D. and Zhurbas, V.M., 2010. Measurements of Turbulence in the Zone of Strong Bottom Currents in the Strait of Denmark. Doklady Earth Sciences, 432(1), pp. 613-617. https://doi.org/10.1134/S1028334X10050144
  4. Samodurov, A.S., Chukharev, A.M., Zubov, A.G. and Pavlenko, O.I., 2015. Structure-Formation and Vertical Turbulent Exchange in the Coastal Area of the Sevastopol Region. Physical Oceanography, (6), pp. 3-16. doi:10.22449/1573-160X-2015-6-3-14
  5. Keller, K.H. and Van Atta, C.W., 2000. An Experimental Investigation of the Vertical Temperature Structure of Homogeneous Stratified Shear Turbulence. Journal of Fluid Mechanics, 425, pp. 1-29. https://doi.org/10.1017/S0022112000002111
  6. Van Haren, H., Gostiaux, L., Morozov, E. and Tarakanov, R., 2014. Extremely Long Kelvin-Helmholtz Billow Trains in the Romanche Fracture Zone. Geophysical Research Letters, 41(23), pp. 8445-8451. https://doi.org/10.1002/2014GL062421
  7. Wunsch, C. and Ferrari, R., 2004. Vertical Mixing, Energy, and the General Circulation of the Oceans. Annual Review of Fluid Mechanics, 36, pp. 281-314. https://doi.org/10.1146/annurev.fluid.36.050802.122121
  8. Holford, J.M. and Linden, P.F., 1999. Turbulent Mixing in a Stratified Fluid. Dynamics of Atmospheres and Oceans, 30(2–4), pp. 173-198. https://doi.org/10.1016/S0377-0265(99)00025-1
  9. Shroyer, E.L., Moum, J.N. and Nash, J.D., 2010. Energy Transformations and Dissipation of Nonlinear Internal Waves over New Jersey’s Continental Shelf. Nonlinear Processes in Geophysic, 17(4), pp. 345-360. https://doi.org/10.5194/npg-17-345-2010
  10. Ostrovskii, A.G. and Zatsepin, A.G., 2016. Intense Ventilation of the Black Sea Pycnocline due to Vertical Turbulent Exchange in the Rim Current Area. Deep Sea Research Part I: Oceanographic Research Papers, 116, pp. 1-13. https://doi.org/10.1016/j.dsr.2016.07.011
  11. De Silva, I.P.D., Brandt, A., Montenegro, L.J. and Fernando, H.J.S., 1999. Gradient Richardson Number Measurements in a Stratified Shear Layer. Dynamics of Atmospheres and Oceans, 30(1), pp. 47-63. https://doi.org/10.1016/S0377-0265(99)00015-9
  12. Troy, C.D. and Koseff, J.R., 2005. The Instability and Breaking of Long Internal Waves. Journal of Fluid Mechanics, 543, pp. 107-136. doi:10.1017/S0022112005006798
  13. Clark, H.A. and Sutherland, B.R., 2010. Generation, Propagation, and Breaking of an Internal Wave Beam. Physics of Fluids, 22(7), 076601. doi:10.1063/1.3455432
  14. Podymov, O.I., Zatsepin, A.G. and Ostrovsky, A.G., 2017. Vertical Turbulent Exchange in the Black Sea Pycnocline and Its Relation to Water Dynamics. Oceanology, 57(4), pp. 492-504. https://doi.org/10.1134/S0001437017040142
  15. Vasil’ev, O.F., Voropaeva, O.F. and Kurbatskii, A.F., 2011. Turbulent Mixing in Stably Stratified Currents of the Environment: The Current State of the Problem (Review). Izvestiya, Atmospheric and Oceanic Physics, 47(3), pp. 265-280. https://doi.org/10.1134/S000143381103011X
  16. Samodurov, A.S., Chukharev, A.M., Nosova, A.V. and Globina, L.V., 2013. Internal Waves Intensification in the Shelf Break Region as a Factor of the Vertical Exchange Intensification. Fundamentalnaya i Prikladnaya Gidrofizika, 6(2), pp. 12-24 (in Russian).
  17. Zhurbas, V.M. and Ozmidov, R.V., 1983. On the Internal Structure of the Fine Stepped Structure of the Main Ocean Thermocline. Oceanology, 23(6), pp. 938-943.
  18. Falina, A.S. and Volkov, I.I., 2005. Influence of Double Diffusion on the General Hydrological Structure of the Deep Waters in the Black Sea. Oceanology, 45(1), pp. 16-25.
  19. Pogrebnoi, A.E. and Samodurov, A.S., 2014. Evolution of Mixed Layers in a Stratified Region of the Black Sea Anticyclonic Eddy. Izvestiya, Atmospheric and Oceanic Physics, 50(6), pp. 621-629. doi:10.7868/S0002351514060121
  20. Romanenkov, D.A., Zimin, A.V., Rodionov, A.A., Atazhanova, O.A. and Kozlov, I.E., 2016. Variability of Fronts and Features of Mesoscale Water Dynamics in the White Sea. Fundamentalnaya i Prikladnaya Gidrofizika, 9(1), pp. 59-72 (in Russian).
  21. Maurer, B.D., Bolster, D.T. and Linden, P.F., 2010. Intrusive Gravity Currents between Two Stably Stratified Fluids. Journal of Fluid Mechanics, 647, pp. 53-69. doi:10.1017/S0022112009993752
  22. Borisenko, Yu.D., Voronovich, A.G., Leonov, A.I. and Miropolsky, Yu.Z., 1976. On the Theory of Nonstationary Weak Nonlinear Internal Waves in Stratified Fluid. Izvestiya AN SSSR, Fizika Atmosfery i Okeana, 12(3), pp. 293-301 (in Russian).
  23. Voronovich, A.G., Leonov, A.I. and Miropolsky, Yu.Z., 1976. On the Theory of Formation of Fine Structure of Hydrophysical Fields in the Ocean. Okeanologiya, 16(5), pp. 750-759 (in Russian).
  24. Le Blon, P.H. and Misek, L.A., 1978. Waves in the Ocean. Amsterdam: Elsevier Scientific Publishing Company. Pt. 2, 365 p.
  25. LeBlond, P.H., 1966. On the Damping of Internal Gravity Waves in a Continuously Stratified Ocean. Journal of Fluid Mechanics, 25(1), pp. 121-142. doi:10.1017/S0022112066000089
  26. Slepyshev, A.A., 2015. Vertical Fluxes Induced by Weak-Nonlinear Internal Waves in a Baroclinic Flow. Physical Oceanography, (1), pp. 59-72. doi:10.22449/1573-160X-2015-1-59-72
  27. Slepyshev, A.A., 2016. Vertical Momentum Transfer by Internal Waves when Eddy Viscosity and Diffusion are Taken into Account. Izvestiya, Atmospheric and Oceanic Physics, 52(3), pp. 301-308. doi:10.1134/S0001433816030117
  28. Vishik, M.I. and Lyusternik, L.A., 1957. Regular Degeneration and Boundary Layer for Linear Differential Equations with Small Parameter. Uspekhi Matematicheskikh Nauk, 12(5), pp. 3-122 (in Russian).
  29. Banks, W.H.H., Drazin, P.G. and Zaturska, M.B., 1976. On the Normal Modes of Parallel Flow of Inviscid Stratified Fluid. Journal of Fluid Mechanics, 75(1), pp. 149-171. doi:10.1017/S0022112076000153
  30. Booker, J.B. and Bretherton, F.P., 1967. The Critical Layer for Internal Gravity Waves in a Shear Flow. Journal of Fluid Mechanics, 27(3), pp. 513-539. doi:10.1017/S0022112067000515
  31. Caillol, P. and Grimshaw, R.H.J., 2012. Internal Solitary Waves with a Weakly Stratified Critical Layer. Physics of Fluids, 24(5), 056602. doi:10.1063/1.4704815
  32. Jones, W.L., 1967. Propagation of Internal Gravity Waves in Fluids with Shear Flow and Rotation. Journal of Fluid Mechanics, 30(3), pp. 439-448. doi:10.1017/S0022112067001521
  33. Watson, G., 1994. Internal Waves in a Stratified Shear Flow: The Strait of Gibraltar. Journal of Physical Oceanography, 24(2), pp. 509-517. doi:10.1175/1520-0485(1994)024<0509:IWIASS>2.0.CO;2
  34. Ivanov, V.A., Samodurov, A.S., Chuharev, A.M. and Nosova, A.V., 2008. Intensification of Vertical Turbulent Exchange in the Interface between the Shelf and the Continental Slope in the Black Sea. Reports of the National Academy of Sciences of Ukraine, (6), pp. 108-112 (in Russian).

Download the article (PDF)

We use Yandex Metrics. Read more.

Мы используем Яндекс Метрику. Подробнее.