Abstract
Until recently, a careful derivation of the fusion structure of anyons from some underlying physical principles has been lacking. In Shi et al. (2020), the authors achieved this goal by starting from a conjectured form of entanglement area law for 2D gapped systems. In this work, we instead start with the principle of exchange symmetry, and determine the minimal prescription of additional postulates needed to make contact with unitary ribbon fusion categories as the appropriate algebraic framework for modelling anyons. Assuming that 2D quasiparticles are spatially localised, we build a functor from the coloured braid groupoid to the category of finite-dimensional Hilbert spaces. Using this functor, we construct a precise notion of exchange symmetry, allowing us to recover the core fusion properties of anyons. In particular, given a system of n quasiparticles, we show that the action of a certain n-braid βn uniquely specifies its superselection sectors. We then provide an overview of the braiding and fusion structure of anyons in the usual setting of braided 6j fusion systems. By positing the duality axiom of Kitaev (2006) and assuming that there are finitely many distinct topological charges, we arrive at the framework of ribbon categories.
Highlights
The study and classification of topological phases of matter is a pervasive theme of contemporary physics
We saw that its action uniquely specified the superselection sectors of a system, illuminated the fusion structure amongst them and suggested the ribbon relation
Using exchange symmetry as our guiding physical principle, we showed that postulates A1-A3 suffice to recover unitary ribbon fusion categories as a framework for modelling anyons
Summary
The study and classification of topological phases of matter is a pervasive theme of contemporary physics. A series of ‘assumptions’ or postulates A1-A3 are given throughout the text They are proposed as the minimal prescription needed to recover ribbon fusion categories (as an algebraic model for anyons) from exchange symmetry in (2 + 1)-dimensions. F and R symbols can be recovered from our construction, and we are able to arrive at the usual formalism (of unitary ribbon fusion categories) for modelling theories of anyons. We recover the core fusion structure amongst these superselection sectors by showing that they exhibit the same statistical behaviour as quasiparticles, allowing us to identify them as such (Theorem 5.5).
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