English

Uniformly accelerated observer in a thermal bath

General Relativity and Quantum Cosmology 2014-02-26 v1 High Energy Physics - Theory

Abstract

We investigate the quantum field aspects in flat spacetime for an uniformly accelerated observer moving in a thermal bath. In particular, we obtain an exact closed expression of the reduced density matrix for an uniformly accelerated observer with acceleration a=2πTa = 2\pi T when the state of the quantum field is a thermal bath at temperature TT^\prime. We find that the density matrix has a simple form with an effective partition function ZZ being a product, Z=ZTZTZ = Z_T Z_{T^\prime}, of two thermal partition functions corresponding to temperatures TT and TT^\prime and hence is not thermal, even when T=TT = T^\prime. We show that, even though the partition function has a product structure, the two thermal baths are, in fact, interacting systems; although in the high frequency limit ωkT\omega_k \gg T and ωkT\omega_k \gg T^\prime, the interactions are found to become sub-dominant. We further demonstrate that the resulting spectrum of the Rindler particles can be interpreted in terms of spontaneous and stimulated emission due to the background thermal bath. The density matrix is also found to be symmetric in the acceleration temperature TT and the thermal bath temperature TT^\prime indicating that thermodynamic experiments alone cannot distinguish between the thermal effects due to TT and those due to TT^\prime. The entanglement entropy associated with the reduced density matrix (with the background contribution of the Davies-Unruh bath removed) is shown to satisfy, in the ωkT\omega_k \gg T^\prime limit, a first law of thermodynamics relation of the form TδS=δET \delta S = \delta E where δE\delta E is the difference in the energies corresponding to the reduced density matrix and the background Davies-Unruh bath. The implications are discussed.

Keywords

Cite

@article{arxiv.1309.3261,
  title  = {Uniformly accelerated observer in a thermal bath},
  author = {Sanved Kolekar},
  journal= {arXiv preprint arXiv:1309.3261},
  year   = {2014}
}

Comments

16 pages, no figure

R2 v1 2026-06-22T01:25:59.791Z