Physics – Condensed Matter – Statistical Mechanics
Scientific paper
2007-07-05
Phys. Rev. E 76, 031132 (2007)
Physics
Condensed Matter
Statistical Mechanics
Version accepted in Phys. Rev. E
Scientific paper
10.1103/PhysRevE.76.031132
The total entropy production generated by the dynamics of an externally driven systems exchanging energy and matter with multiple reservoirs and described by a master equation is expressed as the sum of three contributions, each corresponding to a distinct mechanism for bringing the system out of equilibrium: nonequilibrium initial conditions, external driving, and breaking of detailed balance. We derive three integral fluctuation theorems (FTs) for these contributions and show that they lead to the following universal inequality: an arbitrary nonequilibrium transformation always produces a change in the total entropy production greater or equal than the one produced if the transformation is done very slowly (adiabatically). Previously derived fluctuation theorems can be recovered as special cases. We show how these FTs can be experimentally tested by performing the counting statistics of the electrons crossing a single level quantum dot coupled to two reservoirs with externally varying chemical potentials. The entropy probability distributions are simulated for driving protocols ranging from the adiabatic to the sudden switching limit.
Esposito Massimiliano
Harbola Upendra
Mukamel Shaul
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