Properties of p- and f-modes in hydromagnetic turbulence

Abstract

With the ultimate aim of using the fundamental or f-mode to study helioseismic aspects of turbulence-generated magnetic flux concentrations, we use randomly forced hydromagnetic simulations of a piecewise isothermal layer in two dimensions with reflecting boundaries at top and bottom. We compute numerically diagnostic wavenumber-frequency diagrams of the vertical velocity at the interface between the denser gas below and the less dense gas above. For an Alfv\'en-to-sound speed ratio of about 0.1, a 5% frequency increase of the f-mode can be measured when kxH p=3-4, where kx is the horizontal wavenumber and H p is the pressure scale height at the surface. Since the solar radius is about 2000 times larger than H p, the corresponding spherical harmonic degree would be 6000-8000. For weaker fields, a kx-dependent frequency decrease by the turbulent motions becomes dominant. For vertical magnetic fields, the frequency is enhanced for kxH p≈4, but decreased relative to its nonmagnetic value for kxH p≈9.