Knots Connected by Wide Ribbons

Abstract

A ribbon is, intuitively, a smooth mapping of an annulus S1 × I in 3-space having constant width . This can be formalized as a triple (x,, u) where x is smooth curve in 3-space and u is a unit vector field based along x. In the 1960s and 1970s, G. Calugareanu, G. H. White, and F. B. Fuller proved relationships between the geometry and topology of thin ribbons, in particular the "Link = Twist + Writhe" theorem that has been applied to help understand properties of double-stranded DNA. Although ribbons of small width have been studied extensively, it appears that less is known about ribbons of large width whose images (even via a smooth map) can be singular or self-intersecting. Suppose K is a smoothly embedded knot in R3. Given a regular parameterization x(s), and a smooth unit vector field u(s) based along K, we may define a ribbon of width R associated to x and u as the set of all points x(s) + ru(s), r ∈ [0,R]. For large R, these wide ribbons typically have self-intersections. In this paper, we analyze how the knot type of the outer ribbon edge x(s) + Ru(s) relates to that of the original knot K. We show that, generically, there is an eventual limiting knot type of the outer ribbon edge as R gets arbitrary large. We prove that this eventual knot type is one of only finitely many possibilities which depend just on the vector field u. However, the particular knot type within the finite set depends on the parameterized curves x(s), u(s), and their interactions. Finally, we show how to control the curves and their parameterizations so that given two knot types K1 and K2, we can find a smooth ribbon of constant width connecting curves of these two knot types.