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Hunting The Poles in the Staircases

Christophe Carré, Ulysse Goncalves, Jean-Gabriel Luque

Abstract

Motivated by applications to the fractional quantum Hall effect and, in particular, to the Bernevig-Haldane conjectures, we investigates the behavior of Macdonald polynomials under specializations of the form q a t b = 1. Our main focus is to explain, in a simple and purely combinatorial way, why certain nonsymmetric Macdonald polynomials indexed by staircase vectors with steps of height a and width b remain regular at the specialization q a t b+1 = 1, despite the presence of potential poles in their rational coefficients. To this end, we introduce a set of combinatorial tools that track how poles are created or cancelled along paths in the Yang-Baxter graph. By carefully constructing paths from the zero vector to the staircase and analyzing the resulting denominators, we show that the absence of certain poles follows from intrinsic symmetries and cancellations encoded in the Yang-Baxter graph.

Hunting The Poles in the Staircases

Abstract

Motivated by applications to the fractional quantum Hall effect and, in particular, to the Bernevig-Haldane conjectures, we investigates the behavior of Macdonald polynomials under specializations of the form q a t b = 1. Our main focus is to explain, in a simple and purely combinatorial way, why certain nonsymmetric Macdonald polynomials indexed by staircase vectors with steps of height a and width b remain regular at the specialization q a t b+1 = 1, despite the presence of potential poles in their rational coefficients. To this end, we introduce a set of combinatorial tools that track how poles are created or cancelled along paths in the Yang-Baxter graph. By carefully constructing paths from the zero vector to the staircase and analyzing the resulting denominators, we show that the absence of certain poles follows from intrinsic symmetries and cancellations encoded in the Yang-Baxter graph.
Paper Structure (17 sections, 13 theorems, 103 equations, 3 figures)

This paper contains 17 sections, 13 theorems, 103 equations, 3 figures.

Key Result

Proposition 3

Let $a,b$ be two positive integers and let be a bivariate polynomial. The following statements are equivalent:

Figures (3)

  • Figure 1: Computation of $M_{102}$.
  • Figure 2: From $M_{022330}$ to $M_{33220}$.
  • Figure 3: From $M_{022330}$ to $M_{33220}$.

Theorems & Definitions (25)

  • Claim 1
  • Claim 2
  • Proposition 3
  • proof
  • Lemma 1
  • proof
  • Proposition 4
  • proof
  • Lemma 2: Jumping Lemma
  • proof
  • ...and 15 more