An adjunction theorem for Davydov-Yetter cohomology and infinitesimal braidings
Abstract
Davydov-Yetter cohomology HDY(F) is associated to a monoidal functor F: C D between -linear monoidal categories where is a field, and its second degree classifies the infinitesimal deformations of the monoidal structure of F. Our main result states that if F admits a right adjoint R, then there is an object in the Drinfeld center Z(C) defined in terms of R such that the Davydov-Yetter cohomology of F can be expressed as the Davydov-Yetter cohomology of the identity functor on C with the coefficient . We apply this result in the case when the product functor : C has a monoidal structure given by a braiding c on C and determine explicitly the coefficient as a coend object in Z(C) Z(C). The motivation is that HDY() contains a ``space of infinitesimal braidings tangent to c'' in a way that we describe precisely. For C = H-mod, where H is a finite-dimensional Hopf algebra over a field , this is the Zariski tangent space to the affine variety of R-matrices for H. In the case of perfect , we give a dimension formula for this space as an explicit end involving only (low-degree) relative Ext's of the standard adjunction between Z(C) and C. As a further application of the adjunction theorem, we describe deformations of the restriction functor associated to a Hopf subalgebra and a Drinfeld twist. Both applications are illustrated in the example of bosonization of exterior algebras.
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