Defect Antichains and Multigraded Symbolic Defect Series of Edge Ideals under Graph Blow-ups

Abstract

In this paper, we study symbolic defect functions of edge ideals through finite antichains of exponent vectors. Let G be a finite simple graph and let I(G) be its edge ideal. For each symbolic degree s, we define the symbolic exponent region Ps(G), the ordinary exponent region Os(G), and the symbolic defect antichain Ds(G)=(Ps(G) Os(G)), where the minimum is taken with respect to the componentwise partial order. We prove that Ds(G) gives a finite obstruction set controlling the minimal monomial generators of the quotient I(G)(s)/I(G)s. Our main result is a blow-up transfer formula. If G n is the graph obtained from G by replacing each vertex vi by an independent set of size ni, then for every s≥ 1, \[ sdefect(I(G n),s) = Σ a∈ Ds(G) Πi=1r ai+ni-1ni-1. \] We further refine this formula to a multigraded symbolic defect series, which records the full multidegree distribution of the minimal generators of I(G n)(s)/I(G n)s. As applications, we classify the defect antichains of complete graphs in terms of integer partitions and derive explicit symbolic defect formulas for complete multipartite graphs, complete split graphs, and blow-ups of odd cycles. We also study symbolic defect antichains under graph joins and obtain polynomiality and rational generating-function consequences in the blow-up parameters. The results provide a unified antichain-based framework for symbolic defects of edge ideals and convert several previously case-by-case computations into consequences of a single transfer principle.