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Rook matroids and log-concavity of $P$-Eulerian polynomials

2 Pith papers cite this work. Polarity classification is still indexing.

2 Pith papers citing it
abstract

We define and study rook matroids, the bases of which correspond to non-nesting rook placements on a skew Ferrers board. We show that rook matroids are a subclass of both transversal matroids and positroids; they also bear a subtle relationship to lattice path matroids that centers around not having the quaternary matroid $Q_{6}$ as a minor. The enumerative and distributional properties of non-nesting rook placements stand in contrast to those of usual rook placements: the non-nesting rook polynomial is not real-rooted in general, and is instead ultra-log-concave. We leverage this property together with a correspondence between rook placements and linear extensions of a poset to show that if $P$ is a naturally labeled width two poset, then the $P$-Eulerian polynomial $W_{P}$ is ultra-log-concave. This takes an important step towards resolving a log-concavity conjecture of Brenti (1989) and completes the story of the Neggers--Stanley conjecture for naturally labeled width two posets.

fields

math.CO 2

years

2026 2

verdicts

UNVERDICTED 2

representative citing papers

Ehrhart positivity for lattice path matroids

math.CO · 2026-05-21 · unverdicted · novelty 6.0

All lattice path matroids are Ehrhart positive, unifying prior results and implying positivity for Schubert matroids while supporting conjectures on positroids and Schubitopes.

citing papers explorer

Showing 2 of 2 citing papers.

  • Order polytopes of generalized snake posets are $h^*$-real-rooted math.CO · 2026-07-01 · unverdicted · none · ref 17 · internal anchor

    Proves the conjecture that Ehrhart h*-polynomials of order polytopes of generalized snake posets are real-rooted by connecting them to non-nesting rook polynomials.

  • Ehrhart positivity for lattice path matroids math.CO · 2026-05-21 · unverdicted · none · ref 91 · internal anchor

    All lattice path matroids are Ehrhart positive, unifying prior results and implying positivity for Schubert matroids while supporting conjectures on positroids and Schubitopes.