Abstract Details


Name: AMBIKA SAXENA
Affiliation: ARIES Nainital
Conference ID: TVS202510145
Title: Investigating spectral line asymmetries due to the propagating transverse waves in the solar corona
Authors and Co-Authors: Vaibhav Pant, Tom Van Doorsselaere, M. Saleem Khan
Abstract Type: Contributory Presentation
Abstract: Decades-long studies of asymmetric spectral lines in the solar corona suggest mass and energy transport from lower atmospheric layers to the corona. While slow magnetoacoustic waves and plasma flows are recognized as drivers of these spectral line asymmetries, the role of transverse waves remains largely unexplored. Previous simulations have shown that unidirectionally propagating kink waves,in the presence of perpendicular density inhomogeneities, can produce a turbulence-like phenomenoncalled “uniturbulence.“ However, the spectroscopic signatures of this effect have not been investigated until now. Due to varying Doppler shifts—both blueward and redward—from plasma elements with different emissions, we expect to observe signatures of both types of asymmetry. Past instrumentslike EIS may have missed these signatures due to resolution limitations, but current instruments like DKIST offer a better opportunity for detection. We conducted 3D MHD simulations of transversewaves in a polar plume with density inhomogeneities and performed forward modeling for the Fe XIII emission line at 10749 ˚A. Our findings show that transverse waves and uniturbulence induce alternating red and blueward asymmetries, with magnitudes reaching up to 20% of peak intensity and secondary peak velocities between 30 and 40 km s−1, remaining under 100 km s−1. These asymmetries propagate with the transverse waves, and even at DKIST resolution, similar signatures were observed. Our study suggests that spectral line asymmetries can serve as a diagnostic tool for detecting transverse wave-induced uniturbulence.