Effects of radiative interior on solar inertial modes
Authors
Suprabha Mukhopadhyay
Yuto Bekki
Xiaojue Zhu
Laurent Gizon
Abstract
Solar inertial modes are expected to play important diagnostic and dynamical roles in the Sun's differentially rotating convection zone. The coupling of these modes to the radiative interior is yet to be discussed. We aim to understand the dependence of the modes on the uniformly rotating subadiabatic region below the convection zone, and whether this leads to measurable changes at the surface. We used the Dedalus code to compute the linear eigenmodes in the inertial frequency range in a setup including both the convection zone and the radiative interior down to $0.5 R_\odot$. We imposed free-surface boundary conditions at both radial boundaries. For comparison, we also computed the eigenmodes in a setup restricted to the convection zone. We find that the inclusion of the radiative zone only slightly modifies the frequencies and the eigenfunctions at the surface, excluding some modes with significant radial motions (high-frequency retrograde and prograde columnar modes). On the other hand, most modes penetrate significantly into the overshooting layer below the convection zone, which significantly reduces the growth rate of the modes and distorts their eigenfunctions near the base of the convection zone. Furthermore, the uniformly rotating subadiabatic radiative zone supports oscillations due to Rossby modes of all possible spherical harmonics and radial nodes. In particular, when the nearest inertial mode in frequency space lies within around 10 nHz and shares the same north-south symmetry, these Rossby modes evolve into mixed modes characterized by significant motions within both the radiative and convection zones. However, such mixed modes have a large mode mass in the radiative interior and thus will be difficult to excite stochastically by convection.
