Holographic Theory of Mixed-Dimensional Statistics and Conservation-Encoding Hopping-Operator Algebras

Abstract

We develop a general framework for the statistics of mixed-dimensional excitations subject to intertwined conservation laws, extending the familiar Fermi statistics with conserved particle number. We define statistics microscopically through a hopping-operator algebra: a local operator subalgebra (LOsA) generated by operators that locally move or deform excitations while preserving the conservation law. Nontrivial statistics arise when this subalgebra is nontrivial. We first focus on LOsAs that encode pointed conservation laws. These give rise to invertible excitations, whose fusion rules are exactly those of the symmetry defects of a higher group . For such -conserved excitations in d-dimensional space, we show that the corresponding LOsA -- and hence the statistics it defines -- is classified by a cohomology class [ω] ∈ Hd+2(B;/), where changing [ω] by a coboundary corresponds merely to a rephasing of the local operators. We further provide a holographic realization: excitations with this prescribed conservation law and statistics live on the boundary of a higher-group gauge theory in (d+1)-dimensional space, twisted by [ω]. More generally, non-pointed conservation laws and the associated statistics of non-invertible excitations are defined by a pair: a LOsA together with its excitation-complex representation. This is equivalent to the pair consisting of a LOsA and its Hilbert-space representation, which is the data defining a generalized symmetry. Consequently, non-pointed conservation laws and their statistics in d-dimensional space are classified by fusion d-categories, just as generalized symmetries are. The higher-group results above are the fully-pointed special cases of this more general classification.

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