@article {3194, title = {Non-Abelian symmetry can increase entanglement entropy}, journal = {Physical Review B}, volume = {107}, year = {2023}, month = {1/3/2023}, abstract = {

The pillars of quantum theory include entanglement and operators\&$\#$39; failure to commute. The Page curve quantifies the bipartite entanglement of a many-body system in a random pure state. This entanglement is known to decrease if one constrains extensive observables that commute with each other (Abelian {\textquoteleft}{\textquoteleft}charges\&$\#$39;\&$\#$39;). Non-Abelian charges, which fail to commute with each other, are of current interest in quantum thermodynamics. For example, noncommuting charges were shown to reduce entropy-production rates and may enhance finite-size deviations from eigenstate thermalization. Bridging quantum thermodynamics to many-body physics, we quantify the effects of charges\&$\#$39; noncommutation -- of a symmetry\&$\#$39;s non-Abelian nature -- on Page curves. First, we construct two models that are closely analogous but differ in whether their charges commute. We show analytically and numerically that the noncommuting-charge case has more entanglement. Hence charges\&$\#$39; noncommutation can promote entanglement.

}, doi = {10.1103/physrevb.107.045102}, url = {https://arxiv.org/abs/2209.14303}, author = {Shayan Majidy and Aleksander Lasek and David A. Huse and Nicole Yunger Halpern} }