Normally torsion-free edge ideals of weighted oriented graphs
Abstract
Let I=I(D) be the edge ideal of a weighted oriented graph D, let G be the underlying graph of D, and let I(n) be the n-th symbolic power of I defined using the minimal primes of I. We prove that I2=I(2) if and only if (i) every vertex of D with weight greater than 1 is a sink and (ii) G has no triangles. As a consequence, using a result of Mandal and Pradhan, and the classification of normally torsion-free edge ideals of graphs, it follows that In=I(n) for all n≥ 1 if and only if (a) every vertex of D with weight greater than 1 is a sink and (b) G is bipartite. If I has no embedded primes, conditions (a) and (b) classify when I is normally torsion-free. Using polyhedral geometry and integral closure, we give necessary conditions for the equality of ordinary and symbolic powers of monomial ideals with a minimal irreducible decomposition. Then, we classify when the Alexander dual of the edge ideal of a weighted oriented graph is normally torsion-free.
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