Vanishing of Schubert Coefficients

Schubert coefficients are nonnegative integers $c^w_{u,v}$ that arise in Algebraic Geometry and play a central role in Algebraic Combinatorics. It is a major open problem whether they have a combinatorial interpretation, i.e, whether $c^w_{u,v} \in \#{\sf P}$. We study the closely related vanishing problem of Schubert coefficients: $\{c^w_{u,v}=^?0\}$. Until this work it was open whether this problem is in the polynomial hierarchy ${\sf PH}$. We prove that $\{c^w_{u,v}=^?0\}$ in ${\sf coAM}$ assuming the GRH. In particular, the vanishing problem is in ${\Sigma_2^{{\text{p}}}}$. Our approach is based on constructions lifted formulations, which give polynomial systems of equations for the problem. The result follows from a reduction to Parametric Hilbert's Nullstellensatz, recently studied in arXiv:2408.13027. We apply our construction to show that the vanishing problem is in ${\sf NP}_{\mathbb{C}} \cap {\sf P}_{\mathbb{R}}$ in the Blum--Shub--Smale (BSS) model of computation over complex and real numbers respectively. Similarly, we prove that computing Schubert coefficients is in $\#{\sf P}_{\mathbb{C}}$, a counting version of the BSS model. We also extend our results to classical types. With one notable exception of the vanishing problem in type $D$, all our results extend to all types.