Work extraction from microcanonical bath
Abstract
We determine the maximal work extractable via a cyclic Hamiltonian process from a positive-temperature () microcanonical state of a spin bath. The work is much smaller than the total energy of the bath, but can be still much larger than the energy of a single bath spin, e.g. it can scale as . Qualitatively same results are obtained for those cases, where the canonical state is unstable (e.g., due to a negative specific heat) and the microcanonical state is the only description of equilibrium. For a system coupled to a microcanonical bath the concept of free energy does {\it not generally} apply, since such a system|starting from the canonical equilibrium density matrix at the bath temperature |can enhance the work extracted from the microcanonical bath without changing its state . This is impossible for any system coupled to a canonical thermal bath due to the relation between the maximal work and free energy. But the concept of free energy still applies for a sufficiently large . Here we find a compact expression for the {\it microcanonical free-energy} and show that in contrast to the canonical case it contains a {\it linear entropy} instead of the von Neumann entropy.
Cite
@article{arxiv.1111.4453,
title = {Work extraction from microcanonical bath},
author = {Armen E. Allahverdyan and Karen V. Hovhannisyan},
journal= {arXiv preprint arXiv:1111.4453},
year = {2015}
}
Comments
6 pages, 1 figure