A geometric foundation of virtual knot theory

Abstract

Virtual knots are defined diagrammatically as a collection of figures, called virtual knot diagrams, that are considered equivalent up to finite sequences of extended Reidemeister moves. By contrast, knots in R3 can be defined geometrically. They are the points of a space K of knots. The knot space has a topology so that equivalent knots lie in the same path component. The aim of this paper is to use sheaf theory to obtain a fully geometric model for virtual knots. The geometric model formalizes the intuitive notion that a virtual knot is an actual knot residing in a variable ambient space; the usual diagrammatic theory follows as in the classical case. To do this, it is shown that there exists a site (VK, JVK) so that its category Sh(VK,JVK) of sheaves can be naturally interpreted as the ``space of virtual knots''. A point of this Grothendieck topos, that is a geometric morphism Sets Sh(VK), is a virtual knot. The virtual isotopy relation is generated by paths in this space, or more precisely, geometric morphisms Sh([0,1]) Sh(VK,JVK). Virtual knot invariants valued in a discrete topological space G are geometric morphisms Sh(VK,JVK) Sh(G), just as classical knot invariants valued in G are continuous functions K G. The embedding of classical knots into virtual knots is also realized as a geometric morphism.