Why Do Stars Turn Red? II. Solutions of Steady-State Stellar Structure

To investigate the physical origin of red giants (RGs) and red supergiants (RSGs), we construct steady-state models of stellar envelopes by explicitly solving the stellar structure equations, with boundary conditions set at the stellar surface and the hydrogen burning shell. For comparison, we consider both polytropic and realistic models. Polytropic models adopt a polytropic equation of state (EOS) and neglect energy transport, while realistic models incorporate radiative and convective energy transport, along with tabulated EOS and opacities. Our steady-state solutions reproduce three key features relevant to the evolution toward the RG/RSG phase. First, the refined mirror principle of \cite{Ou2024} is reproduced: the stellar radius varies inversely with the radius of the envelope's inner boundary, defined by the burning shell's surface. This feature arises purely from hydrostatic equilibrium, as it appears in both polytropic and realistic models. Second, realistic models reveal an upper limit to envelope expansion, corresponding to an effective temperature of $\sim4,000\,{\rm K}$, which is characteristic of RG/RSG stars and consistent with the classical Hayashi limit. Approaching this limit, the envelope undergoes a structural transition marked by a significant change in the density profile and the formation of an extended convective zone. The location of this limit is governed by the sharp drop in H$^{-}$ opacity as the envelope cools below $\sim10,000\,{\rm K}$. Finally, our solutions show that even a small shift in the envelope's inner boundary can induce substantial envelope expansion throughout the yellow regime, naturally explaining the bifurcation of giants and supergiants into red and blue branches.