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4.1: Introduction

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    141611

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    That the central temperatures of stars are higher than their surface temperatures can no longer be in doubt. The laws of thermodynamics thus ensure that energy will flow from the center of stars to their surfaces. The physical processes that accomplish this will basically establish the temperature gradient within the star. This is the remaining relationship required for us to link the interior structure with that of the surface. The temperature gradient and along with the conservation laws of mass and energy provide the three independent relationships necessary to relate the three state variables to the values they must have at the boundaries of the star.

    Energy can move through a medium by essentially three ways, and they can each be characterized by the gas particles which carry the energy and the forces which resist these efforts. These mechanisms are radiative transfer, convective transport, and conductive transfer, of energy. The efficiency of these processes is determined primarily by the amount of energy that can be carried by the particles, their number and their speed. These variables set an upper limit to the rate of energy transport. In addition, the "opacity" of the material to the motion of the energy-carrying particles will also affect the efficiency. In the case of radiation, we have characterized this opacity by a collision cross section and the density. Another way to visualize this is via the notion of a mean free path. This is just the average distance between collisions experienced by the particles. In undergoing a collision, the particle will give up some of its energy thereby losing its efficiency as a transporter of energy. We will see that, in general, there are large differences in the mean free paths for the particles that carry energy by these three mechanisms, and so one mechanism will usually dominate in the transfer of energy.

    Before we can describe the radiative flow of energy, we must understand how the presence of matter impedes that flow. Thus we shall begin our discussion of the transport of energy by determining how the local radiative opacity depends on local values of the state variables. From the assumption of strict thermodynamic equilibrium (STE) we know that any impediment to the flow can be described in terms of a parameter that depends only on the temperature. However, to calculate that parameter, we have to investigate the detailed dependence of the opacity on frequency.

    This page titled 4.1: Introduction 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.