Universal Coefficients and Mayer-Vietoris Sequence for Groupoid Homology

Abstract

We study homology of ample groupoids via the compactly supported Moore complex of the nerve. Let A be a topological abelian group. For n 0 set Cn( G;A) := Cc( Gn,A) and define ∂nA=Σi=0n(-1)i(di)*. This defines Hn( G;A). The theory is functorial for continuous \'etale homomorphisms. It is compatible with standard reductions, including restriction to saturated clopen subsets. In the ample setting it is invariant under Kakutani equivalence. We reprove Matui type long exact sequences and identify the comparison maps at chain level. For discrete A we prove a natural universal coefficient short exact sequence 0 Hn( G) ZA\ n G\ Hn( G;A)\ n G\ Tor1 Z(Hn-1( G),A) 0. The key input is the chain level isomorphism Cc( Gn, Z) ZA Cc( Gn,A), which reduces the groupoid statement to the classical algebraic UCT for the free complex Cc( G, Z). We also isolate the obstruction for non-discrete coefficients. For a locally compact totally disconnected Hausdorff space X with a basis of compact open sets, the image of X:Cc(X, Z) ZA Cc(X,A) is exactly the compactly supported functions with finite image. Thus X is surjective if and only if every f∈ Cc(X,A) has finite image, and for suitable X one can produce compactly supported continuous maps X A with infinite image. Finally, for a clopen saturated cover G0=U1 U2 we construct a short exact sequence of Moore complexes and derive a Mayer-Vietoris long exact sequence for H( G;A) for explicit computations.