Entropy of Static Spacetimes and Microscopic Density of States
Abstract
A general ansatz for gravitational entropy can be provided using the criterion that, any patch of area which acts as a horizon for a suitably defined accelerated observer, must have an entropy proportional to its area. After providing a brief justification for this ansatz, several consequences are derived: (i) In any static spacetime with a horizon and associated temperature β-1, this entropy satisfies the relation S=(1/2)β E where E is the energy source for gravitational acceleration, obtained as an integral of (Tab-(1/2)Tgab)uaub. (ii) With this ansatz of S, the minimization of Einstein-Hilbert action is equivalent to minimizing the free energy F with β F=β U-S where U is the integral of Tabuaub. We discuss the conditions under which these results imply S E2 and/or S U2 thereby generalizing the results known for black holes. This approach links with several other known results, especially the holographic views of spacetime.
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