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11.6: Hydrostatic Equilibrium and the Stellar Atmosphere

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    Any discussion of the environment of the radiation field would be incomplete without some mention of the motions to be expected within the atmosphere. Recently, considerable effort has been expended in describing radiation-driven winds that originate in the outer reaches of the atmospheres of hot stars. This more advanced topic is well beyond the scope of our interest at this point. Instead, we take advantage of the fact that radiation is the primary mode of energy transport through the stellar atmosphere, and we assume that the atmosphere is in hydrostatic equilibrium. While turbulent convection is present in many stars, the motions implied by the observed velocities are likely to cause problems only for the stars with the lowest surface gravities. For stars on the main sequence, hydrostatic equilibrium is an excellent assumption.

    The notion of hydrostatic equilibrium has been mentioned repeatedly throughout this book from the general concept obtained from the Boltzmann transport equation in Chapter 1, through the explicit formulation for spherical stars given by equation \ref{2.1.6} to the representation for plane-parallel atmospheres found in equation \ref{9.1.1}. However, the introduction of the concept of optical depth allows for a further refinement. Since the logical depth variable for radiative transfer is the optical depth variable \(\tau_\nu\), it makes some sense to reformulate the other structure equations that explicitly involve the depth coordinate to reflect the use of the optical depth and the independent variable of the structure. Some atmosphere modeling codes use a variant of equation \ref{9.1.1}, \[\frac{1}{\rho} \frac{d P}{d x}=-g\label{11.5.1}\]

    so that the quantity ρdx is the depth variable. A more common formulation takes advantage of the definition of the optical depth \[d \tau_\nu=-\left(\kappa_\nu+\sigma_\nu\right) \rho d x\label{11.5.2}\]

    which yields the condition for hydrostatic equilibrium in terms of the optical depth. Thus, \[\frac{d P}{d \tau_\nu}=\frac{g}{\kappa_\nu+\sigma_\nu}\label{11.5.3}\]

    Having described the environment of the radiation field in terms of the state variables P, T, and ρ, we can now proceed to the actual construction of a model atmosphere.

    This page titled 11.6: Hydrostatic Equilibrium and the Stellar Atmosphere is shared under a Public Domain license and was authored, remixed, and/or curated by George W. Collins II (Pachart Foundation) via source content that was edited to the style and standards of the LibreTexts platform.