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6.1: Introduction

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    141631

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    In the next two chapters we consider some specific problems which lie outside the realm of normal stellar structure. In the past several decades, it has become increasingly clear that a large number of stars require some further subtleties of physics for their proper description. Two areas that we shall consider involve the initial assumption of spherical symmetry and the assumption that the gravitational field can be described by the Newtonian theory of gravity with sufficient accuracy to properly represent the star. In this chapter, we investigate some of the ramifications of the general theory of relativity for highly condensed objects and super-massive stars.

    Although the application of the general theory of relativity to astronomical problems has a long and venerable history dating back to Einstein himself, it was not until the discovery of pulsars in the 1960s that a great deal of interest was directed toward the impact of the theory on stellar structure. To be sure, the pioneering theoretical work was done 30 years earlier and can be traced back to Landau1 in 1932. The fundamental work of Oppenheimer2,3 and collaborators still provides the fundamental basis for most models requiring general relativity for their representation. But it was the discovery that neutron stars actually existed and were probably the result of the dynamical collapse of a supernova that led to the construction of modern models that represent our contemporary view of these objects.

    It is not my intent to provide a complete description of the general theory of relativity in order that the reader is able to understand all the ramifications for stellar structure implied by that theory. For that, the reader is referred to “Gravitation” by Misner, Thorne, and Wheeler4. Rather, let us outline the origin of the fundamental equations of relativistic stellar structure and the results of their applications to some simple objects, without the rigors of their complete derivation. The intent here is to provide some physical insight into the role played by general relativity in a variety of objects for which that role is important.

    This page titled 6.1: 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.