A Seifert algorithm for integral homology spheres
Abstract
From classical knot theory we know that every knot in S3 is the boundary of an oriented, embedded surface. A standard demonstration of this fact achieved by elementary technique comes from taking a regular projection of any knot and employing Seifert's constructive algorithm. In this note we give a natural generalization of Seifert's algorithm to any closed integral homology 3-sphere. The starting point of our algorithm is presenting the handle structure of a Heegaard splitting of a given integral homology sphere as a planar diagram on the boundary of a 3-ball. (For a well known example of such a planar presentation, see the Poincar\'e homology sphere planar presentation in Knots and Links by D. Rolfsen Rolfsen.) An oriented link can then be represented by the regular projection of an oriented k-strand tangle. From there we give a natural way to find a ``Seifert circle" and associated half-twisted bands.
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