Mixed-State Long-Range Entanglement from Dimensional Constraints
Abstract
We present a new mechanism for long-range entanglement (LRE) in strongly symmetric many-body mixed states that does not rely on symmetry anomalies or long-range correlations. Our primary example is the maximally mixed state in the translation-invariant subspace on a one-dimensional ring. This state is LRE because translationally symmetric short-range entangled states span a subspace whose dimension grows only polynomially with system size, whereas the full translation-invariant subspace grows exponentially. We further discuss certain unconventional properties of this state, including logarithmically growing conditional mutual information, strong-to-weak spontaneous symmetry-breaking, and R\'enyi-index-dependent operator-space entanglement. We also construct a geometrically non-local Lindbladian to stabilize this state as the steady state. Our results identify dimensional mismatch as a novel route to LRE that is intrinsic to many-body mixed states.
Cite
@article{arxiv.2605.15201,
title = {Mixed-State Long-Range Entanglement from Dimensional Constraints},
author = {Leonardo A. Lessa and Tsung-Cheng Lu},
journal= {arXiv preprint arXiv:2605.15201},
year = {2026}
}
Comments
27 pages, 2+8 figures