Algebraic subdivision in simplicially controlled categories

Abstract

We generalise the notion of subdivision of a finite-dimensional locally finite simplicial complex X to geometric algebra, namely to the simplicially controlled categories A*(X), A*(X) of Ranicki and Weiss. We prove a squeezing result: a bounded chain equivalence of sufficiently algebraically subdivided chain complexes can be squeezed to a simplicially controlled chain equivalence of the unsubdivided chain complexes. Giving X×R a bounded triangulation measured in the open cone O(X+) we use algebraic subdivision to define a functor "-":B(A(X)) B(A(X×R)) that corresponds to tensoring with the simplicial chain complex of Z and algebraically subdividing to be bounded over O(X+). We show that C 0 ∈ B(A(X)) if and only if "C" is boundedly chain contractible over O(X+). These results have applications to Poincar\'e duality and homology manifold detection as a finite-dimensional locally finite simplicial complex X is a homology manifold if and only if it has X-controlled Poincar\'e duality. We prove a Poincar\'e duality squeezing theorem that such a space X with sufficiently controlled Poincar\'e duality must have X-controlled Poincar\'e duality and we prove a Poincar\'e duality splitting theorem with the consequence that X is a homology manifold if and only if X×R has bounded Poincar\'e duality over O(X+).