A Red Giants' Toy Story

TL;DR

This paper provides a simple analytical explanation for why stars become red giants, supported by a toy model that aligns with full stellar evolution models, revealing tight relations between core properties and stellar expansion.

Contribution

It introduces a novel analytical approach and toy model that explain red giant formation and validate key stellar relations, enhancing understanding of stellar evolution.

Findings

Envelope forces narrow the temperature gradient range at the burning shell.

Relations between shell variables and core properties are tightly constrained.

Evolution causes increased pressure and density contrasts, leading to stellar expansion.

Abstract

In spite of the spectacular progress accomplished by stellar evolution theory some simple questions remain unanswered. One of these questions is ``Why do stars become Red Giants?''. Here we present a relatively simple analytical answer to this question. We validate our analysis by constructing a quantitative toy-model of a red giant and comparing its predictions to full stellar evolutionar models. We find that the envelope forces the value of $\nabla=d \ln T/d \ln P$ at, and above, the burning shell into a very narrow range of possible values. Together with the fact that the stellar material at the burning shell both provides and transports most of the stellar luminosity, this leads to tight relations between the thermodynamic variables at the burning shell and the mass and radius of the core -- $T_s(M_c,R_s)$, $P_s(M_c,R_s)$ and $\rho_s(M_c,R_s)$. When complemented by typical mass-radius relations of the helium cores, this implies that for all stellar masses the evolution of the core dictates the values of $T_s$, $P_s$ and $\rho_s$. We show that for all stellar masses evolution leads to an increase in the pressure and density contrasts between the shell and the core, forcing a huge expansion of the layers on top of the burning shell. Besides explaining why stars become red giants our analysis also offers a mathematical demonstration of the so-called shell homology relations, and provides simple quantitative answers to some properties of low-mass red giants.