Superuniversality of superdiffusion
Abstract
Anomalous finite-temperature transport has recently been observed in numerical studies of various integrable models in one dimension; these models share the feature of being invariant under a continuous non-abelian global symmetry. This work offers a comprehensive group-theoretic account of this elusive phenomenon. For an integrable quantum model invariant under a global non-abelian simple Lie group , we find that finite-temperature transport of Noether charges associated with symmetry in thermal states that are invariant under is universally superdiffusive and characterized by dynamical exponent . This conclusion holds regardless of the Lie algebra symmetry, local degrees of freedom (on-site representations), Lorentz invariance, or particular realization of microscopic interactions: we accordingly dub it as superuniversal. The anomalous transport behavior is attributed to long-lived giant quasiparticles dressed by thermal fluctuations. We provide an algebraic viewpoint on the corresponding dressing transformation and elucidate formal connections to fusion identities amongst the quantum-group characters. We identify giant quasiparticles with nonlinear soliton modes of classical field theories that describe low-energy excitations above ferromagnetic vacua. Our analysis of these field theories also provides a complete classification of the low-energy (i.e., Goldstone-mode) spectra of quantum isotropic ferromagnetic chains.
Cite
@article{arxiv.2009.08425,
title = {Superuniversality of superdiffusion},
author = {Enej Ilievski and Jacopo De Nardis and Sarang Gopalakrishnan and Romain Vasseur and Brayden Ware},
journal= {arXiv preprint arXiv:2009.08425},
year = {2021}
}
Comments
44 pages, 9 figures, 5 tables (minor corrections)