Integrability and complexity in quantum spin chains

There is a widespread perception that dynamical evolution of integrable systems should be simpler in a quantifiable sense than the evolution of generic systems, though demonstrating this relation between integrability and reduced complexity in practice has remained elusive. We provide a connection o...

Full description

Saved in:
Bibliographic Details
Published inSciPost physics Vol. 16; no. 2; p. 041
Main Authors Craps, Ben, De Clerck, Marine, Evnin, Oleg, Hacker, Philip
Format Journal Article
LanguageEnglish
Published SciPost 01.02.2024
Online AccessGet full text

Cover

Loading…
More Information
Summary:There is a widespread perception that dynamical evolution of integrable systems should be simpler in a quantifiable sense than the evolution of generic systems, though demonstrating this relation between integrability and reduced complexity in practice has remained elusive. We provide a connection of this sort by constructing a specific matrix in terms of the eigenvectors of a given quantum Hamiltonian. The null eigenvalues of this matrix are in one-to-one correspondence with conserved quantities that have simple locality properties (a hallmark of integrability). The typical magnitude of the eigenvalues, on the other hand, controls an explicit bound on Nielsen’s complexity of the quantum evolution operator, defined in terms of the same locality specifications. We demonstrate how this connection works in a few concrete examples of quantum spin chains that possess diverse arrays of highly structured conservation laws mandated by integrability.
ISSN:2542-4653
2542-4653
DOI:10.21468/SciPostPhys.16.2.041