Geodesic
Algebraic linking numbers of knots in 3–manifolds
Schneiderman, Rob1
1Courant Institute of Mathematical Sciences, New York University, 251 Mercer Street, New York NY 10012-1185, USA
Algebraic and Geometric Topology, Tome 3 (2003) no. 2, pp. 921-968
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Relative self-linking and linking “numbers” for pairs of oriented knots and 2–component links in oriented 3–manifolds are defined in terms of intersection invariants of immersed surfaces in 4–manifolds. The resulting concordance invariants generalize the usual homological notion of linking by taking into account the fundamental group of the ambient manifold and often map onto infinitely generated groups. The knot invariants generalize the type 1 invariants of Kirk and Livingston and when taken with respect to certain preferred knots, called spherical knots, relative self-linking numbers are characterized geometrically as the complete obstruction to the existence of a singular concordance which has all singularities paired by Whitney disks. This geometric equivalence relation, called W–equivalence, is also related to finite type 1–equivalence (in the sense of Habiro and Goussarov) via the work of Conant and Teichner and represents a “first order” improvement to an arbitrary singular concordance. For null-homotopic knots, a slightly weaker equivalence relation is shown to admit a group structure.

DOI : 10.2140/agt.2003.3.921
Keywords: concordance invariant, knots, linking number, 3–manifold

Schneiderman, Rob  1

1 Courant Institute of Mathematical Sciences, New York University, 251 Mercer Street, New York NY 10012-1185, USA 
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Schneiderman, Rob. Algebraic linking numbers of knots in 3–manifolds. Algebraic and Geometric Topology, Tome 3 (2003) no. 2, pp. 921-968. doi: 10.2140/agt.2003.3.921

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