English

Schur Function Expansions and the Rational Shuffle Theorem

Combinatorics 2020-04-14 v3

Abstract

Gorsky and Negut introduced operators Qm,nQ_{m,n} on symmetric functions and conjectured that, in the case where mm and nn are relatively prime, the expression Qm,n(1){Q}_{m,n}(1) is given by the Hikita polynomial Hm,n[X;q,t]{H}_{m,n}[X;q,t]. Later, Bergeron-Garsia-Leven-Xin extended and refined the conjectures of Qm,n(1){Q}_{m,n}(1) for arbitrary mm and nn which we call the Extended Rational Shuffle Conjecture. In the special case Qn+1,n(1){Q}_{n+1,n}(1), the Rational Shuffle Conjecture becomes the Shuffle Conjecture of Haglund-Haiman-Loehr-Remmel-Ulyanov, which was proved in 2015 by Carlsson and Mellit as the Shuffle Theorem. The Extended Rational Shuffle Conjecture was later proved by Mellit as the Extended Rational Shuffle Theorem. The main goal of this paper is to study the combinatorics of the coefficients that arise in the Schur function expansion of Qm,n(1){Q}_{m,n}(1) in certain special cases. Leven gave a combinatorial proof of the Schur function expansion of Q2,2n+1(1){Q}_{2,2n+1}(1) and Q2n+1,2(1){Q}_{2n+1,2}(1). In this paper, we explore several symmetries in the combinatorics of the coefficients that arise in the Schur function expansion of Qm,n(1){Q}_{m,n}(1). Especially, we study the hook-shaped Schur function coefficients, and the Schur function expansion of Qm,n(1){Q}_{m,n}(1) in the case where mm or nn equals 33.

Keywords

Cite

@article{arxiv.1806.04348,
  title  = {Schur Function Expansions and the Rational Shuffle Theorem},
  author = {Dun Qiu and Jeffrey Remmel},
  journal= {arXiv preprint arXiv:1806.04348},
  year   = {2020}
}

Comments

35 pages, 18 figures

R2 v1 2026-06-23T02:26:48.962Z