Ropelength

In physical knot theory, each realization of a link or knot has an associated ropelength. Intuitively this is the minimal length of an ideally flexible rope that is needed to tie a given link, or knot. Knots and links that minimize ropelength are called ideal knots and ideal links respectively.

A numeric approximation of an ideal trefoil.

Definition

The ropelength of a knotted curve [math]\displaystyle{ C }[/math] is defined as the ratio [math]\displaystyle{ L(C) = \operatorname{Len}(C)/\tau(C) }[/math], where [math]\displaystyle{ \operatorname{Len}(C) }[/math] is the length of [math]\displaystyle{ C }[/math] and [math]\displaystyle{ \tau(C) }[/math] is the knot thickness of [math]\displaystyle{ C }[/math].

Ropelength can be turned into a knot invariant by defining the ropelength of a knot [math]\displaystyle{ K }[/math] to be the minimum ropelength over all curves that realize [math]\displaystyle{ K }[/math].

Ropelength minimizers

One of the earliest knot theory questions was posed in the following terms:

In terms of ropelength, this asks if there is a knot with ropelength [math]\displaystyle{ 12 }[/math]. The answer is no: an argument using quadrisecants shows that the ropelength of any nontrivial knot has to be at least [math]\displaystyle{ 15.66 }[/math].^[1] However, the search for the answer has spurred research on both theoretical and computational ground. It has been shown that for each link type there is a ropelength minimizer although it may only be of differentiability class [math]\displaystyle{ C^1 }[/math].^[2][3] For the simplest nontrivial knot, the trefoil knot, computer simulations have shown that its minimum ropelength is at most 16.372.^[1]

Dependence on crossing number

An extensive search has been devoted to showing relations between ropelength and other knot invariants such as the crossing number of a knot. For every knot [math]\displaystyle{ K }[/math], the ropelength of [math]\displaystyle{ K }[/math] is at least proportional to [math]\displaystyle{ \operatorname{Cr}(K)^{3/4} }[/math], where [math]\displaystyle{ \operatorname{Cr}(K) }[/math] denotes the crossing number.^[4] There exist knots and links, namely the [math]\displaystyle{ (k,k-1) }[/math] torus knots and [math]\displaystyle{ k }[/math]-Hopf links, for which this lower bound is tight. That is, for these knots (in big O notation),^[3] [math]\displaystyle{ L(K)=O(\operatorname{Cr}(K)^{3/4}). }[/math]

On the other hand, there also exist knots whose ropelength is larger, proportional to the crossing number itself rather than to a smaller power of it.^[5] This is nearly tight, as for every knot, [math]\displaystyle{ L(K)= O(\operatorname{Cr}(K)\log^5(\operatorname{Cr}(K))). }[/math] The proof of this near-linear upper bound uses a divide-and-conquer argument to show that minimum projections of knots can be embedded as planar graphs in the cubic lattice.^[6] However, no one has yet observed a knot family with super-linear dependence of length on crossing number and it is conjectured that the tight upper bound should be linear.^[7]

References

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