Abstract
Usually, in a nonequilibrium setting, a current brings mass from the highest density regions to the lowest density ones. Although rare, the opposite phenomenon (known as "uphill diffusion") has also been observed in multicomponent systems, where it appears as an artificial effect of the interaction among components. We show here that uphill diffusion can be a substantial effect, i.e., it may occur even in single component systems as a consequence of some external work. To this aim we consider the two-dimensional ferromagnetic Ising model in contact with two reservoirs that fix, at the left and the right boundaries, magnetizations of the same magnitude but of opposite signs.We provide numerical evidence that a class of nonequilibrium steady states exists in which, by tuning the reservoir magnetizations, the current in the system changes from "downhill" to "uphill". Moreover, we also show that, in such nonequilibrium setup, the current vanishes when the reservoir magnetization attains a value approaching, in the large volume limit, the magnetization of the equilibrium dynamics, thus establishing a relation between equilibrium and nonequilibrium properties.
Highlights
When a metal bar is put in contact at its extremity with two heat sources at different temperatures, heat is transported from one side to the other
In this paper it is argued that uphill diffusion appears in the non-equilibrium Ising model coupled to magnetization reservoirs
First we observe that our results imply no violation of the thermodynamic principles
Summary
When a metal bar is put in contact at its extremity with two heat sources at different temperatures, heat is transported from one side to the other. Non-equilibrium 2D Ising model with stationary uphill diffusion Matteo Colangeli,1 Cristian Giardina,2 Claudio Giberti,2 and Cecilia Vernia2 1University of L’Aquila, Via Vetoio, 67100 L’Aquila, Italy.
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