Stellar oscillations. II The non-adiabatic case

TL;DR

This paper discusses the energetical aspects of stellar pulsations using non-adiabatic equations, explaining driving and damping mechanisms, and relates these to recent space-borne observations and scaling relations in asteroseismology.

Contribution

It introduces a comprehensive analysis of non-adiabatic stellar oscillations, emphasizing physical mechanisms and their connection to observational data and scaling relations.

Findings

Distinction between self-excited and solar-like oscillations.

Explanation of physical mechanisms driving and damping pulsations.

Connection of non-adiabatic physics to seismic scaling relations.

Abstract

A leap forward has been performed due to the space-borne missions, MOST, CoRoT and Kepler. They provided a wealth of observational data, and more precisely oscillation spectra, which have been (and are still) exploited to infer the internal structure of stars. While an adiabatic approach is often sufficient to get information on the stellar equilibrium structures it is not sufficient to get a full understanding of the physics of the oscillation. Indeed, it does not permit one to answer some fundamental questions about the oscillations, such as: What are the physical mechanisms responsible for the pulsations inside stars? What determines the amplitudes? To what extent the adiabatic approximation is valid? All these questions can only be addressed by considering the energy exchanges between the oscillations and the surrounding medium. This lecture therefore aims at considering the energetical aspects of stellar pulsations with particular emphasis on the driving and damping mechanisms. To this end, the full non-adiabatic equations are introduced and thoroughly discussed. Two types of pulsation are distinguished, namely the self-excited oscillations that result from an instability and the solar-like oscillations that result from a balance between driving and damping by turbulent convection. For each type, the main physical principles are presented and illustrated using recent observations obtained with the ultra-high precision photometry space-borne missions (MOST, CoRoT and Kepler). Finally, we consider in detail the physics of scaling relations, which relates the seismic global indices with the global stellar parameters and gave birth to the development of statistical (or ensemble) asteroseismology. Indeed, several of these relations rely on the same cause: the physics of non-adiabatic oscillations.