(Co)cyclic (co)homology of bialgebroids: An approach via (co)monads

Abstract

For a (co)monad Tl on a category M, an object X in M, and a functor : M C, there is a (co)simplex Z*:= Tl* +1 X in C. Our aim is to find criteria for para-(co)cyclicity of Z*. Construction is built on a distributive law of Tl with a second (co)monad Tr on M, a natural transformation i: Tl Tr, and a morphism w: Tr X Tl X in M. The relations i and w need to satisfy are categorical versions of Kaygun's axioms of a transposition map. Motivation comes from the observation that a (co)ring T over an algebra R determines a distributive law of two (co)monads Tl=T R (-) and Tr = (-)R T on the category of R-bimodules. The functor can be chosen such that Zn= TR... R T R X is the cyclic R-module tensor product. A natural transformation i:T R (-) (-) R T is given by the flip map and a morphism w: X R T TR X is constructed whenever T is a (co)module algebra or coring of an R-bialgebroid. Stable anti Yetter-Drinfel'd modules over certain bialgebroids, so called xR-Hopf algebras, are introduced. In the particular example when T is a module coring of a xR-Hopf algebra B and X is a stable anti Yetter-Drinfel'd B-module, the para-cyclic object Z* is shown to project to a cyclic structure on TR *+1 B X. For a B-Galois extension S T, a stable anti Yetter-Drinfel'd B-module TS is constructed, such that the cyclic objects BR *+1 B TS and T S *+1 are isomorphic. As an application, we compute Hochschild and cyclic homology of a groupoid with coefficients, by tracing it back to the group case. In particular, we obtain explicit expressions for ordinary Hochschild and cyclic homology of a groupoid.