Concept
In mathematics, a commutativity constraint on a is a choice of isomorphism for each pair of objects A and B which form a "natural family." In particular, to have a commutativity constraint, one must have for all pairs of objects . A braided monoidal category is a monoidal category equipped with a braiding—that is, a commutativity constraint that satisfies axioms including the hexagon identities defined below. The term braided references the fact that the braid group plays an important role in the theory of braided monoidal categories. Partly for this reason, braided monoidal categories and other topics are related in the theory of knot invariants. Alternatively, a braided monoidal category can be seen as a with one 0-cell and one 1-cell. Braided monoidal categories were introduced by André Joyal and Ross Street in a 1986 preprint. A modified version of this paper was published in 1993. For along with the commutativity constraint to be called a braided monoidal category, the following hexagonal diagrams must commute for all objects . Here is the associativity isomorphism coming from the on : It can be shown that the natural isomorphism along with the maps coming from the monoidal structure on the category , satisfy various coherence conditions, which state that various compositions of structure maps are equal. In particular: The braiding commutes with the units. That is, the following diagram commutes: The action of on an -fold tensor product factors through the braid group. In particular, as maps . Here we have left out the associator maps. There are several variants of braided monoidal categories that are used in various contexts. See, for example, the expository paper of Savage (2009) for an explanation of symmetric and coboundary monoidal categories, and the book by Chari and Pressley (1995) for ribbon categories. Symmetric monoidal category A braided monoidal category is called symmetric if also satisfies for all pairs of objects and . In this case the action of on an -fold tensor product factors through the symmetric group.
Kathryn Hess Bellwald, Inbar Klang