Meaning of temperature in different thermostatistical ensembles

Author(s)

Hänggi, Peter; Hilbert, Stefan; Dunkel, Joern

Abstract

Depending on the exact experimental conditions, the thermodynamic properties of physical systems can be related to one or more thermostatistical ensembles. Here, we survey the notion of thermodynamic temperature in different statistical ensembles, focusing in particular on subtleties that arise when ensembles become non-equivalent. The ‘mother’ of all ensembles, the microcanonical ensemble, uses entropy and internal energy (the most fundamental, dynamically conserved quantity) to derive temperature as a secondary thermodynamic variable. Over the past century, some confusion has been caused by the fact that several competing microcanonical entropy definitions are used in the literature, most commonly the volume and surface entropies introduced by Gibbs. It can be proved, however, that only the volume entropy satisfies exactly the traditional form of the laws of thermodynamics for a broad class of physical systems, including all standard classical Hamiltonian systems, regardless of their size. This mathematically rigorous fact implies that negative ‘absolute’ temperatures and Carnot efficiencies more than 1 are not achievable within a standard thermodynamical framework. As an important offspring of microcanonical thermostatistics, we shall briefly consider the canonical ensemble and comment on the validity of the Boltzmann weight factor. We conclude by addressing open mathematical problems that arise for systems with discrete energy spectra.

Date issued

2016-02

URI

http://hdl.handle.net/1721.1/109523

Department

Massachusetts Institute of Technology. Department of Mathematics

Journal

Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences

Publisher

Royal Society, The

Citation

Hänggi, Peter, Stefan Hilbert, and Jörn Dunkel. “Meaning of Temperature in Different Thermostatistical Ensembles.” Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences 374, no. 2064 (February 22, 2016): 20150039.

Version: Original manuscript

ISSN

1364-503X

1471-2962