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Effect of latitudinal differential rotation on solar Rossby waves: Critical layers, eigenfunctions, and momentum fluxes in the equatorial<i>β</i>plane

L. Gizon, D. Fournier, M. Albekioni

2020Astronomy and Astrophysics27 citationsDOIOpen Access PDF

Abstract

Context. Retrograde-propagating waves of vertical vorticity with longitudinal wavenumbers between 3 and 15 have been observed on the Sun with a dispersion relation close to that of classical sectoral Rossby waves. The observed vorticity eigenfunctions are symmetric in latitude, peak at the equator, switch sign near 20°–30°, and decrease at higher latitudes. Aims. We search for an explanation that takes solar latitudinal differential rotation into account. Methods. In the equatorial β plane, we studied the propagation of linear Rossby waves (phase speed c &lt; 0) in a parabolic zonal shear flow, U = − U̅ ξ 2 &lt; 0, where U̅ = 244 m s −1 , and ξ is the sine of latitude. Results. In the inviscid case, the eigenvalue spectrum is real and continuous, and the velocity stream functions are singular at the critical latitudes where U = c . We add eddy viscosity to the problem to account for wave attenuation. In the viscous case, the stream functions solve a fourth-order modified Orr-Sommerfeld equation. Eigenvalues are complex and discrete. For reasonable values of the eddy viscosity corresponding to supergranular scales and above (Reynolds number 100 ≤ Re ≤ 700), all modes are stable. At fixed longitudinal wavenumber, the least damped mode is a symmetric mode whose real frequency is close to that of the classical Rossby mode, which we call the R mode. For Re ≈ 300, the attenuation and the real part of the eigenfunction is in qualitative agreement with the observations (unlike the imaginary part of the eigenfunction, which has a larger amplitude in the model). Conclusions. Each longitudinal wavenumber is associated with a latitudinally symmetric R mode trapped at low latitudes by solar differential rotation. In the viscous model, R modes transport significant angular momentum from the dissipation layers toward the equator.

Topics & Concepts

PhysicsDifferential rotationRossby waveEigenfunctionWavenumberRossby numberVorticityPotential vorticityClassical mechanicsRossby radius of deformationDispersion relationStream functionAngular momentumInertial waveInviscid flowNormal modeZonal flow (plasma)Turbulence modelingHelioseismologyAmplitudeLatitudeSolar rotationMechanicsShear flowEigenvalues and eigenvectorsAstrophysicsShear (geology)Dispersion (optics)EddyContinuous spectrumMathematical analysisVortexMomentum (technical analysis)Quantum electrodynamicsLongitudeComputational physicsGeopotentialRotation (mathematics)Mean flowSolar and Space Plasma DynamicsOceanographic and Atmospheric ProcessesGeomagnetism and Paleomagnetism Studies