Local moves on knots and products of knots II

Abstract

We use the terms, knot product and local move, as defined in the text of the paper. Let n be an integer≥q3. Let Sn be the set of simple spherical n-knots in Sn+2. Let m be an integer≥q4. We prove that the map j: S2m S2m+4 is bijective, where j(K)=K, and Hopf denotes the Hopf link. Let J and K be 1-links in S3. Suppose that J is obtained from K by a single pass-move, which is a local-move on 1-links. Let k be a positive integer. Let PkQ denote the knot product PQ... Qk. We prove the following: The (4k+1)-dimensional submanifold Jk Hopf ⊂ S4k+3 is obtained from Kk Hopf by a single (2k+1,2k+1)-pass-move, which is a local-move on (4k+1)-submanifolds contained in S4k+3. See the body of the paper for the definitions of all local moves in this abstract. We prove the following: Let a,b,a',b' and k be positive integers. If the (a,b) torus link is pass-move equivalent to the (a',b') torus link, then the Brieskorn manifold (a,b,2,...,22k) is diffeomorphic to (a',b',2,...,22k) as abstract manifolds. Let J and K be (not necessarily connected or spherical) 2-dimensional closed oriented submanifolds in S4. Suppose that J is obtained from K by a single ribbon-move, which is a local-move on 2-dimensional submanifolds contained in S4. Let k be an integer≥2. We prove the following: The (4k+2)-submanifold Jk Hopf ⊂ S4k+4 is obtained from Kk Hopf by a single (2k+1,2k+2)-pass-move, which is a local-move on (4k+2)-dimensional submanifolds contained in S4k+4.