English

Two-variable Conway polynomial and Cochran's derived invariants

Geometric Topology 2024-06-14 v3

Abstract

We note that the Conway potential function ΩL\Omega_L of an mm-component link LL, m>1m>1, can be expressed as ΩL(x1,,xm)=ΘL(L(x1x11,,xmxm1))\Omega_L(x_1,\dots,x_m)=\Theta_L(\nabla_L(x_1-x_1^{-1},\dots,x_m-x_m^{-1})) for a unique LZ[z1,,zm]\nabla_L\in\mathbb Z[z_1,\dots,z_m], where ΘL\Theta_L is a certain endomorphism of the additive group of Z[x1±1,,xm±1]\mathbb Z[x_1^{\pm1},\dots,x_m^{\pm1}] which depends only on the pairwise linking numbers of the components of LL. Motivated by applications to topological isotopy, we study the formal power series ˉL\bar\nabla_L, obtained by dividing L\nabla_L by the Conway polynomials of the components of LL. For a 22-component link with lk(L)=0lk(L)=0, the coefficient α1,2k1\alpha_{1,2k-1} of ˉL(u,v)\bar\nabla_L(u,v) at uv2k1uv^{2k-1} equals Cochran's derived invariant (1)k+1βk(L)(-1)^{k+1}\beta^k(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 α1,2k1\alpha_{1,2k-1} in the geometrically subtler case lk(L)=1lk(L)=1. Namely we express it in terms of generalized Cochran invariants βFij(P,Q)\beta_F^{ij}(P,Q), which were studied by Gilmer--Livingston (when P=QP=Q) and by Tsukamoto--Yasuhara (when j=0j=0) and are closely related to the Cochran pairing in the infinite cyclic covering of a knot.

Keywords

Cite

@article{arxiv.math/0312007,
  title  = {Two-variable Conway polynomial and Cochran's derived invariants},
  author = {Sergey A. Melikhov},
  journal= {arXiv preprint arXiv:math/0312007},
  year   = {2024}
}

Comments

36 pages, 1 figure. v3: Much of the paper is new, inculding the main result. Some material from the old version has moved to a new preprint