Anomalous self-diffusion in the ferromagnetic Ising chain with Kawasaki dynamics

Abstract

We investigate the motion of a tagged spin in a ferromagnetic Ising chain evolving under Kawasaki dynamics. At equilibrium, the displacement is Gaussian, with a variance growing as A t1/2. The temperature dependence of the prefactor A is derived exactly. At low temperature, where the static correlation length is large, the mean square displacement grows as (t/2)2/3 in the coarsening regime, i.e., as a finite fraction of the mean square domain length. The case of totally asymmetric dynamics, where (+) (resp. (-)) spins move only to the right (resp. to the left), is also considered. In the steady state, the displacement variance grows as B t2/3. The temperature dependence of the prefactor B is derived exactly, using the Kardar-Parisi-Zhang theory. At low temperature, the displacement variance grows as t/2 in the coarsening regime, again proportionally to the mean square domain length.

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