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Entanglement Entropy Growth in Disordered Spin Chains with Tunable Range Interactions

Disordered Systems and Neural Networks 2023-03-07 v1 Materials Science Quantum Physics

Abstract

The non-equilibrium dynamics of disordered many-body quantum systems after a global quantum quench unveils important insights about the competition between interactions and disorder, yielding in particular an insightful perspective on many body localization (MBL). Still, the experimentally relevant effect of bond randomness in long-range interacting spin chains on the quantum quench dynamics have so far not been investigated. In this letter, we examine the entanglement entropy growth after a global quench in a quantum spin chain with randomly placed spins and long-range tunable interactions decaying with distance with power α\alpha. Using a dynamical version of the strong disorder renormalization group (SDRG) we find for α>αc\alpha >\alpha_c that the entanglement entropy grows logarithmically with time and becomes smaller with larger α\alpha as S(t)=Spln(t)/(2α)S(t) = S_p \ln(t)/(2\alpha). Here, Sp=2ln21S_p= 2 \ln2 -1. We use numerical exact diagonalization (ED) simulations to verify our results for system sizes up to N16 N\sim 16 spins, yielding good agreement for sufficiently large α>αc1.8\alpha > \alpha_c \approx 1.8. For α<αc\alpha<\alpha_c, we find that the entanglement entropy grows as a power-law with time, S(t)tγ(α)S(t)\sim t^{\gamma(\alpha)} with 0<γ(α)<10<\gamma(\alpha)<1 a decaying function of the interaction exponent α\alpha.

Keywords

Cite

@article{arxiv.2303.02415,
  title  = {Entanglement Entropy Growth in Disordered Spin Chains with Tunable Range Interactions},
  author = {Youcef Mohdeb and Javad Vahedi and Ravindra N. Bhatt and Stephan Haas and Stefan Kettemann},
  journal= {arXiv preprint arXiv:2303.02415},
  year   = {2023}
}
R2 v1 2026-06-28T09:01:22.306Z