Quantum knots and the number of knot mosaics

Abstract

Lomonaco and Kauffman developed a knot mosaic system to introduce a precise and workable definition of a quantum knot system. This definition is intended to represent an actual physical quantum system. A knot (m,n)-mosaic is an m × n matrix of mosaic tiles (T0 through T10 depicted in the introduction) representing a knot or a link by adjoining properly that is called suitably connected. D(m,n) is the total number of all knot (m,n)-mosaics. This value indicates the dimension of the Hilbert space of these quantum knot system. D(m,n) is already found for m,n ≤ 6 by the authors. In this paper, we construct an algorithm producing the precise value of D(m,n) for m,n ≥ 2 that uses recurrence relations of state matrices that turn out to be remarkably efficient to count knot mosaics. D(m,n) = 2 \, \| (Xm-2+Om-2)n-2 \| where 2m-2 × 2m-2 matrices Xm-2 and Om-2 are defined by Xk+1 = bmatrix Xk & Ok \\ Ok & Xk bmatrix \ and \ Ok+1 = bmatrix Ok & Xk \\ Xk & 4 \, Ok bmatrix for k=0,1, ·s, m-3, with 1 × 1 matrices X0 = bmatrix 1 bmatrix and O0 = bmatrix 1 bmatrix. Here \|N\| denotes the sum of all entries of a matrix N. For n=2, (Xm-2+Om-2)0 means the identity matrix of size 2m-2 × 2m-2.