Numerical determination of the cutoff frequency in solar models

TL;DR

This paper introduces a numerical method to accurately determine the cutoff frequency in solar atmospheric models, revealing significant deviations from theoretical predictions and emphasizing the roles of magnetic fields and radiative losses.

Contribution

The authors developed a numerical approach to measure the cutoff frequency in solar models, accounting for magnetic fields and radiative effects, which improves upon existing theoretical estimates.

Findings

Numerical cutoff frequencies differ significantly from theoretical predictions.

Radiative losses reduce the cutoff frequency and its dependence on magnetic field strength.

Inclined magnetic fields lower the cutoff frequency due to reduced effective gravity.

Abstract

In stratified atmospheres, acoustic waves can only propagate if their frequency is above the cutoff value. Different theories provide different cutoff values. We developed an alternative method to derive the cutoff frequency in several standard solar models, including various quiet-Sun and umbral atmospheres. We performed numerical simulations of wave propagation in the solar atmosphere. The cutoff frequency is determined from the inspection of phase difference spectra computed between the velocity signal at two atmospheric heights. The process is performed by choosing pairs of heights across all the layers between the photosphere and the chromosphere, to derive the vertical stratification of the cutoff in the solar models. The cutoff frequency predicted by the theoretical calculations departs significantly from our measurements. In quiet-Sun atmospheres, the cutoff shows a strong dependence on the magnetic field for adiabatic wave propagation. When radiative losses are taken into account, the cutoff frequency is greatly reduced and the variation of the cutoff with the strength of the magnetic field is lower. The effect of the radiative losses in the cutoff is necessary to understand recent quiet-Sun and sunspot observations. In the presence of inclined magnetic fields, our numerical calculations confirm the reduction of the cutoff frequency due to the reduced gravity experienced by waves propagating along field lines. An additional reduction is also found in regions with significant changes in the temperature, due to the lower temperature gradient along the path of field-guided waves. Our results show that the cutoff values are not correctly captured by theoretical estimates. In addition, most of the widely-used analytical cutoff formulae neglect the impact of magnetic fields and radiative losses, whose role is critical to determine the evanescent or propagating nature of the waves.