The geometric Hopf invariant and surgery theory

Abstract

The first author's geometric Hopf invariant of a stable map F:∞X ∞Y is a stable Z2-equivariant map h(F):∞X ∞(Y Y) constructed by an explicit difference construction applied to (F F)X - Y F. The stable Z2-equivariant homotopy class of h(F) is the primary obstruction to desuspending F up to homotopy. The explicit nature of the construction allows for a π-equivariant version of h(F) in the case of a π-equivariant F, with π a discrete group. In earlier joint work we applied the π1(N)-equivariant geometric Hopf invariant of the Umkehr map F:∞N+ ∞T(f) of an immersion f:M N to capture the double points of f in Z2-equivariant homotopy theory. In this manuscript we use the π-equivariant geometric Hopf invariant h(F) to unify all the previous homotopy theoretic treatments of double points. Furthermore, h(F) is combined with the second author's algebraic surgery theory of chain complexes with Poincar\'e duality to provide the homotopy theoretic foundations for non-simply-connected geometric surgery. For an n-dimensional normal map (f,b):M X the π1(X)-equivariant geometric Hopf invariant h(F) of the Umkehr map F:∞X+ ∞M+ is shown to induce the π1(X)-equivariant quadratic structure F on the chain complex kernel C of (f,b). Previously F had only been constructed using the chain complex analogue of the functional Steenrod squares. The Wall surgery obstruction σ*(f,b)=(C,F) ∈ Ln( Z[π1(X)]) is the cobordism class of the corresponding n-dimensional quadratic Poincar\'e complex (C,F), as in the original theory.