English

Computation and sampling for Schubert specializations

Combinatorics 2026-03-23 v1 Algebraic Geometry Probability

Abstract

We present computational results on principal specializations Sw(1n)\mathfrak{S}_w(1^n) of Schubert polynomials, which count reduced pipe dreams and reduced bumpless pipe dreams (RBPD). We find the first counterexample, at n=17n=17, to the Merzon-Smirnov conjecture (arXiv:1410.6857) that the maximum of Sw(1n)\mathfrak{S}_w(1^n) over SnS_n is attained at a layered permutation. The simulations suggest that limnlog(maxwSnSw(1n))/n2\lim_{n \to \infty} \log(\max_{w\in S_n}\mathfrak{S}_w(1^n))/n^2 equals the maximal layered permutations' constant from Morales-Pak-Panova (arXiv:1805.04341). We also explore the random permutation drawn from the distribution proportional to Sw(1n)\mathfrak{S}_w(1^n), revealing permuton-like asymptotics similar to those for Grothendieck polynomials by Morales-Panova-Petrov-Yeliussizov (arXiv:2407.21653). We implement and compare three recurrences for Sw(1n)\mathfrak{S}_w(1^n): the descent formula (Macdonald), transition formula (Lascoux--Schutzenberger), and cotransition formula (Knutson). For sampling uniformly random RBPDs (whose count is wSnSw(1n)\sum_{w\in S_n} \mathfrak{S}_w(1^n)), we show that reducedness breaks the sublattice property of the ASM lattice, preventing monotone CFTP and causing false coalescence. We develop an efficient MCMC sampler with macroscopic "droop" updates for connectivity and fast mixing. Our code computes Sw(1n)\mathfrak{S}_w(1^n) up to n20n\sim 20 and samples random RBPDs up to n60n\sim 60 on a personal computer (n100n\sim 100 on a cluster).

Keywords

Cite

@article{arxiv.2603.20104,
  title  = {Computation and sampling for Schubert specializations},
  author = {David Anderson and Greta Panova and Leonid Petrov},
  journal= {arXiv preprint arXiv:2603.20104},
  year   = {2026}
}

Comments

33 pages, 17 figures

R2 v1 2026-07-01T11:30:01.326Z