Magnetization distribution in the transverse Ising chain with energy flux

Abstract

The zero-temperature transverse Ising chain carrying an energy flux jE is studied with the aim of determining the nonequilibrium distribution functions, P(Mz) and P(Mx), of its transverse and longitudinal magnetizations, respectively. An exact calculation reveals that P(Mz) is a Gaussian both at jE=0 and jE not equal 0, and the width of the distribution decreases with increasing energy flux. The distribution of the order-parameter fluctuations, P(Mx), is evaluated numerically for spin-chains of up to 20 spins. For the equilibrium case (jE=0), we find the expected Gaussian fluctuations away from the critical point while the critical order-parameter fluctuations are shown to be non-gaussian with a scaling function Phi(x)=Phi(Mx/<Mx>)=<Mx>P(Mx) strongly dependent on the boundary conditions. When jE not equal 0, the system displays long-range, oscillating correlations but P(Mx) is a Gaussian nevertheless, and the width of the Gaussian decreases with increasing jE. In particular, we find that, at critical transverse field, the width has a jE(-3/8) asymptotic in the jE -> 0 limit.

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