Bridge position and the representativity of spatial graphs

Abstract

First, we extend Otal's result for the trivial knot to trivial spatial graphs, namely, we show that for any bridge tangle decomposing sphere S2 for a trivial spatial graph , there exists a 2-sphere F such that F contains and F intersects S2 in a single loop. Next, we introduce two invariants for spatial graphs. As a generalization of the bridge number for knots, we define the bridge string number bs() of a spatial graph as the minimal number of | S2| for all bridge tangle decomposing sphere S2. As a spatial version of the representativity for a graph embedded in a surface, we define the representativity of a non-trivial spatial graph as \[ r()=F∈F D∈DF |∂ D |, \] where F is the set of all closed surfaces containing and DF is the set of all compressing disks for F in S3. Then we show that for a non-trivial spatial graph , \[ r() bs()2. \] In particular, if is a knot, then r() b(), where b() denotes the bridge number. This generalizes Schubert's result on torus knots.