Two-variable Conway polynomial and Cochran's derived invariants
Abstract
We note that the Conway potential function L of an m-component link L, m>1, can be expressed as L(x1,…,xm)=L(∇L(x1-x1-1,…,xm-xm-1)) for a unique ∇L∈ Z[z1,…,zm], where L is a certain endomorphism of the additive group of Z[x11,…,xm1] which depends only on the pairwise linking numbers of the components of L. Motivated by applications to topological isotopy, we study the formal power series ∇L, obtained by dividing ∇L by the Conway polynomials of the components of L. For a 2-component link with lk(L)=0, the coefficient α1,2k-1 of ∇L(u,v) at uv2k-1 equals Cochran's derived invariant (-1)k+1βk(L). While this can be deduced from a result of G.-T. Jin, which he proved using the surgical view of the Alexander polynomial, we provide an alternative proof, using Seifert matrices. Our main result is a formula for the same coefficient α1,2k-1 in the geometrically subtler case lk(L)=1. Namely we express it in terms of generalized Cochran invariants βFij(P,Q), which were studied by Gilmer--Livingston (when P=Q) and by Tsukamoto--Yasuhara (when j=0) and are closely related to the Cochran pairing in the infinite cyclic covering of a knot.
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