Waves in the lower solar atmosphere: the dawn of next-generation solar telescopes

TL;DR

This paper reviews recent advances in observing and analyzing waves in the lower solar atmosphere, emphasizing new techniques, scientific progress, and open questions driven by next-generation solar telescopes.

Contribution

It provides a comprehensive overview of wave analysis methods and recent scientific discoveries, highlighting future challenges in solar physics research with advanced telescopes.

Findings

Advances in wave analysis techniques for the lower solar atmosphere

Recent scientific discoveries about wave phenomena in the Sun's lower atmosphere

Identification of open questions and future research directions

Abstract

Waves and oscillations have been observed in the Sun's atmosphere for over half a century. While such phenomena have readily been observed across the entire electromagnetic spectrum, spanning radio to gamma-ray sources, the underlying role of waves in the supply of energy to the outermost extremities of the Sun's corona has yet to be uncovered. Of particular interest is the lower solar atmosphere, including the photosphere and chromosphere, since these regions harbor the footpoints of powerful magnetic flux bundles that are able to guide oscillatory motion upwards from the solar surface. As a result, many of the current- and next-generation ground-based and space-borne observing facilities are focusing their attention on these tenuous layers of the lower solar atmosphere in an attempt to study, at the highest spatial and temporal scales possible, the mechanisms responsible for the generation, propagation, and ultimate dissipation of energetic wave phenomena. Here, we present a two-fold review that is designed to overview both the wave analyses techniques the solar physics community currently have at their disposal, as well as highlight scientific advancements made over the last decade. Importantly, while many ground-breaking studies will address and answer key problems in solar physics, the cutting-edge nature of their investigations will naturally pose yet more outstanding observational and/or theoretical questions that require subsequent follow-up work. This is not only to be expected, but should be embraced as a reminder of the era of rapid discovery we currently find ourselves in. We will highlight these open questions and suggest ways in which the solar physics community can address these in the years and decades to come.