Numerical study of effect of wave phase on Reynolds stresses and turbulent kinetic energy in Langmuir turbulence

The dynamics of Reynolds stresses and turbulent kinetic energy (TKE) in Langmuir turbulence are analysed using data of large-eddy simulations with the wave phase resolved. It is found that the streamwise and spanwise Reynolds normal stresses and the Reynolds shear stress vary appreciably with the wa...

Full description

Saved in:
Bibliographic Details
Published inJournal of fluid mechanics Vol. 904
Main Authors Xuan, Anqing, Deng, Bing-Qing, Shen, Lian
Format Journal Article
LanguageEnglish
Published Cambridge, UK Cambridge University Press 10.12.2020
Subjects
Correlation
Correlation analysis
Energy
Energy transfer
Flow control
Frequency spectra
Frequency spectrum
JFM Papers
Kinetic energy
Langmuir turbulence
Langmuir waves
Large eddy simulation
Normal stress
Numerical analysis
Oceanic eddies
Phase variations
Pressure effects
Reynolds stresses
Shear stress
Shearing
Simulation
Turbulence
Velocity
Vortices
Wave period
Wave phase
wave–turbulence interactions
Online AccessGet full text

Cover

More Information
Summary:The dynamics of Reynolds stresses and turbulent kinetic energy (TKE) in Langmuir turbulence are analysed using data of large-eddy simulations with the wave phase resolved. It is found that the streamwise and spanwise Reynolds normal stresses and the Reynolds shear stress vary appreciably with the wave phase, while the vertical normal stress is only weakly dependent on the wave phase. Budget analyses indicate that the production due to wave straining and the effects associated with turbulence pressure are the dominant mechanisms for the wave-phase variation of Reynolds stresses. The accumulative effect of wave–turbulence interactions on TKE is then investigated using the Lagrangian average. It is discovered that the energy transfer from wave to turbulence is contributed by two mechanisms. The first mechanism is the turbulence production by the Lagrangian mean wave shearing and the mean shear stress, which is consistent with the traditional wave-phase-averaged model. The second mechanism, which is not accounted for in previous studies, is the correlation between the wave-phase variation of the Reynolds shear stress and the wave orbital shearing. A model is proposed for the second mechanism. Comparison of the frequency spectrum with Craik–Leibovich simulation results shows that the correlation effect can affect the turbulence fluctuations at time scales around the wave period, indicating the importance of this effect on Reynolds stresses and TKE.
ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2020.688