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Imaginary-time Quantum Relaxation Critical Dynamics with Semi-ordered Initial States

Statistical Mechanics 2023-05-09 v2 Strongly Correlated Electrons

Abstract

We explore the imaginary-time relaxation dynamics near quantum critical points with semi-ordered initial states. Different from the case with homogeneous ordered initial states, in which the order parameter MM decays homogeneously as Mτβ/νzM\propto \tau^{-\beta/\nu z}, here MM depends on the location xx, showing rich scaling behaviors. Similar to the classical relaxation dynamics with an initial domain wall in Model A, which describes the purely dissipative dynamics, here as the imaginary time evolves, the domain wall expands into an interfacial region with growing size. In the interfacial region, the local order parameter decays as Mτβ1/νzM\propto \tau^{-\beta_1/\nu z}, with β1\beta_1 being an additional dynamic critical exponent. Far away from the interfacial region the local order parameter decays as Mτβ/νzM\propto \tau^{-\beta/\nu z} in the short-time stage, then crosses over to the scaling behavior of Mτβ1/νzM\propto \tau^{-\beta_1/\nu z} when the location xx is absorbed in the interfacial region. A full scaling form characterizing these scaling properties is developed. The quantum Ising model in both one and two dimensions are taken as examples to verify the scaling theory. In addition, we find that for the quantum Ising model the scaling function is an analytical function and β1\beta_1 is not an independent exponent.

Keywords

Cite

@article{arxiv.2210.03979,
  title  = {Imaginary-time Quantum Relaxation Critical Dynamics with Semi-ordered Initial States},
  author = {Zhi-Xuan Li and Shuai Yin and Yu-Rong Shu},
  journal= {arXiv preprint arXiv:2210.03979},
  year   = {2023}
}

Comments

7 pages, 5 figures

R2 v1 2026-06-28T03:03:33.992Z