Phys Rev Lett. 2026 Feb 27;136(8):086601. doi: 10.1103/4jww-6b6t.
ABSTRACT
Anyons, unique to two spatial dimensions, underlie extraordinary phenomena such as the fractional quantum Hall effect, but their generalization to higher dimensions has remained elusive. The topology of Eilenberg-MacLane spaces constrains the loop statistics to be only bosonic or fermionic in any dimension. In this Letter, we introduce the novel anyonic statistics for membrane excitations in four dimensions. Analogous to the Z_{N} particle exhibiting Z_{N×gcd(2,N)} anyonic statistics in two dimensions, we show that the Z_{N} membrane possesses Z_{N×gcd(3,N)} anyonic statistics in four dimensions. Given unitary volume operators that create membrane excitations on the boundary, we propose an explicit 56-step unitary sequence that detects the membrane statistics. We further analyze the boundary theory of (5+1)D 1-form Z_{N} symmetry-protected topological phases and demonstrate that their domain walls realize all possible anyonic membrane statistics. We then show that the Z_{3} subgroup persists in all higher dimensions. In addition to the standard fermionic Z_{2} membrane statistics arising from Stiefel-Whitney classes, membranes also exhibit Z_{3} statistics associated with Pontryagin classes. We explicitly verify that the 56-step process detects the nontrivial Z_{3} statistics in five, six, and seven spatial dimensions. Moreover, in seven and higher dimensions, the statistics of membrane excitations stabilize to Z_{2}×Z_{3}, with the Z_{3} sector consistently captured by this process.
PMID:41824970 | DOI:10.1103/4jww-6b6t
