Accelerated Observers, Thermal Entropy, and Spacetime Curvature

Abstract

Assuming that an accelerated observer with four-velocity u R in a curved spacetime attributes the standard Bekenstein-Hawking entropy and Unruh temperature to his "local Rindler horizon", we show that the change in horizon area under parametric displacements of the horizon has a very specific thermodynamic structure. Specifically, it entails information about the time-time component of the Einstein tensor: G( u R, u R). Demanding that the result holds for all accelerated observers, this actually becomes a statement about the full Einstein tensor, G. We also present some perspectives on the free fall with four-velocity u ff across the horizon that leads to such a loss of entropy for an accelerated observer. Motivated by results for some simple quantum systems at finite temperature T, we conjecture that at high temperatures, there exists a universal, system-independent curvature correction to partition function and thermal entropy of any freely falling system, characterised by the dimensional quantity = R( u ff, u ff) ( c/kT )2.