Clausius entropy for arbitrary bifurcate null surfaces

TL;DR

This paper extends Jacobson's thermodynamic derivation of Einstein's equations to arbitrary bifurcate null surfaces, defining a meaningful Clausius entropy for them and exploring its implications for the generalized second law and energy conditions.

Contribution

It introduces a framework to assign Clausius entropy to arbitrary bifurcate null surfaces, broadening the scope of thermodynamic gravity principles beyond local Rindler horizons.

Findings

Clausius entropy can be meaningfully defined for arbitrary bifurcate null surfaces.

A version of the generalized second law applies to this virtual Clausius entropy.

Connections to null energy conditions are established.

Abstract

Jacobson's thermodynamic derivation of the Einstein equations was originally applied only to local Rindler horizons. But at least some parts of that construction can usefully be extended to give meaningful results for arbitrary bifurcate null surfaces. As presaged in Jacobson's original article, this more general construction sharply brings into focus the questions: Is entropy objectively "real"? Or is entropy in some sense subjective and observer-dependent? These innocent questions open a Pandora's box of often inconclusive debate. A consensus opinion, though certainly not universally held, seems to be that Clausius entropy (thermodynamic entropy, defined via a Clausius relation dS = dQ/T) should be objectively real, but that the ontological status of statistical entropy (Shannon or von Neumann entropy) is much more ambiguous, and much more likely to be observer-dependent. This question is particularly pressing when it comes to understanding Bekenstein entropy (black hole entropy). To perhaps further add to the confusion, we shall argue that even the Clausius entropy can often be observer-dependent. In the current article we shall conclusively demonstrate that one can meaningfully assign a notion of Clausius entropy to arbitrary bifurcate null surfaces --- effectively defining a "virtual Clausius entropy" for arbitrary "virtual (local) causal horizons". As an application, we see that we can implement a version of the generalized second law (GSL) for this virtual Clausius entropy. This version of GSL can be related to certain (nonstandard) integral variants of the null energy condition (NEC). Because the concepts involved are rather subtle, we take some effort in being careful and explicit in developing our framework. In future work we will apply this construction to generalize Jacobson's derivation of the Einstein equations.