Related papers: Krylov Complexity Meets Confinement

Krylov Complexity Meets Confinement

URL: http://arxiv.org/abs/2511.03783v1
Date: Wed, 05 Nov 2025 19:00:01 GMT
Title: Krylov Complexity Meets Confinement
Authors: Xuhao Jiang, Jad C. Halimeh, N. S. Srivatsa,
Abstract summary: In high-energy physics, confinement denotes the tendency of fundamental particles to remain bound together.<n>In the Ising model, domain walls become confined into meson-like bound states as a result of a longitudinal field-induced linear potential.<n>We show that confinement manifests as a pronounced suppression of Krylov complexity growth following quenches within the ferromagnetic phase.
Score: 4.949050544434141
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: In high-energy physics, confinement denotes the tendency of fundamental particles to remain bound together, preventing their observation as free, isolated entities. Interestingly, analogous confinement behavior emerges in certain condensed matter systems, for instance, in the Ising model with both transverse and longitudinal fields, where domain walls become confined into meson-like bound states as a result of a longitudinal field-induced linear potential. In this work, we employ the Ising model to demonstrate that Krylov state complexity--a measure quantifying the spread of quantum information under the repeated action of the Hamiltonian on a quantum state--serves as a sensitive and quantitative probe of confinement. We show that confinement manifests as a pronounced suppression of Krylov complexity growth following quenches within the ferromagnetic phase in the presence of a longitudinal field, reflecting slow correlation dynamics. In contrast, while quenches within the paramagnetic phase exhibit enhanced complexity with increasing longitudinal field, reflecting the absence of confinement, those crossing the critical point to the ferromagnetic phase reveal a distinct regime characterized by orders-of-magnitude larger complexity and display trends of weak confinement. Notably, in the confining regime, the complexity oscillates at frequencies corresponding to the meson masses, with its power-spectrum peaks closely matching the semiclassical predictions.

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