Where Multipartite Entanglement Localizes: The Junction Law for Genuine Multi-Entropy

Abstract

We uncover a "junction law" for genuine multipartite entanglement, suggesting that in gapped local systems multipartite entanglement is controlled and effectively localized near junctions where subsystem boundaries meet. Using the R\'enyi-2 genuine multi-entropy GM(q)2 as a diagnostic of genuine q-partite entanglement, we establish this behavior in (2+1)-dimensional gapped free-fermion lattices with correlation length . For partitions with a single junction, GM(q)2 exhibits a universal scaling crossover in L/, growing for L and saturating to a -dependent constant for L, up to O(e-L/) corrections. In sharp contrast, for partitions without a junction, GM(q)2 is exponentially suppressed in L/ and drops below numerical resolution once L. We observe the same pattern for q=3 (tripartite) and q=4 (quadripartite) cases, and further corroborate this localization by translating the junction at fixed system size. We also provide a geometric explanation of the junction law in holography. Altogether, these results show that in this gapped free-fermion setting genuine multipartite entanglement is localized within a correlation-length neighborhood of junctions.