Quenching along a gapless line: A different exponent for defect density

Abstract

We use a new quenching scheme to study the dynamics of a one-dimensional anisotropic XY spin-1/2 chain in the presence of a transverse field which alternates between the values h+ and h- from site to site. In this quenching scheme, the parameter denoting the anisotropy of interaction () is linearly quenched from -∞ to +∞ as = t/τ, keeping the total strength of interaction J fixed. The system traverses through a gapless phase when is quenched along the critical surface h2 = 2 + J2 in the parameter space spanned by h, and . By mapping to an equivalent two-level Landau-Zener problem, we show that the defect density in the final state scales as 1/τ1/3, a behavior that has not been observed in previous studies of quenching through a gapless phase. We also generalize the model incorporating additional alternations in the anisotropy or in the strength of the interaction, and derive an identical result under a similar quenching. Based on the above results, we propose a general scaling of the defect density with the quenching rate τ for quenching along a gapless critical line.