Adiabatic quantum dynamics of a random Ising chain across its quantum critical point

Abstract

We present here our study of the adiabatic quantum dynamics of a random Ising chain across its quantum critical point. The model investigated is an Ising chain in a transverse field with disorder present both in the exchange coupling and in the transverse field. The transverse field term is proportional to a function (t) which, as in the Kibble-Zurek mechanism, is linearly reduced to zero in time with a rate τ-1, (t)=-t/τ, starting at t=-∞ from the quantum disordered phase (=∞) and ending at t=0 in the classical ferromagnetic phase (=0). We first analyze the distribution of the gaps -- occurring at the critical point c=1 -- which are relevant for breaking the adiabaticity of the dynamics. We then present extensive numerical simulations for the residual energy E res and density of defects k at the end of the annealing, as a function of the annealing inverse rate τ. %for different lenghts of the chain. Both the average E res(τ) and k(τ) are found to behave logarithmically for large τ, but with different exponents, [E res(τ)/L] av 1/ζ(τ) with ζ≈ 3.4, and [k(τ)] av 1/2(τ). We propose a mechanism for 1/2τ-behavior of [k] av based on the Landau-Zener tunneling theory and on a Fisher's type real-space renormalization group analysis of the relevant gaps. The model proposed shows therefore a paradigmatic example of how an adiabatic quantum computation can become very slow when disorder is at play, even in absence of any source of frustration.