Detection of wave activity within a realistic 3D MHD quiet sun simulation

Abstract: Context. Tracing wave activity from the photosphere to the corona has important implications for coronal heating and prediction of the solar wind. Despite extensive theory and simulations, the detection of waves in realistic MHD simulations still presents a large challenge due to wave interaction, mode conversion, and damping mechanisms. Aims. We conducted this study to detect localised wave activity within a realistic MHD simulation of the solar atmosphere by the Bifrost code. Methods. We present a new method of detecting the most significant contributions of wave activity within localised areas of the domain, aided by Discrete Fourier Transforms and frequency filtering. We correlate oscillations in the vertical & horizontal magnetic field, velocities parallel & perpendicular to the magnetic field, and pressure to infer the nature of the dominant wave modes. Results. Our method captures the most powerful frequencies and wavenumbers, as well as providing a new diagnostic for damping processes. We infer the presence of magnetoacoustic waves in the boundaries of prominent chromospheric/coronal swirling features. We find these waves are likely damped by viscous heating in the swirl boundaries, contributing to heating in the upper atmosphere. Conclusions. Using the most significant frequencies decomposition, we highlight that energy can be transported from the lower atmosphere to the upper atmosphere through waves and fluctuations along the swirl boundaries. Although further analysis is needed to confirm these findings, our new method provides a path forward to investigate wave activity in the solar atmosphere