Noncolliding Macdonald Walks with an Absorbing Wall

Abstract

The branching rule is one of the most fundamental properties of the Macdonald symmetric polynomials. It expresses a Macdonald polynomial as a nonnegative linear combination of Macdonald polynomials with smaller number of variables. Taking a limit of the branching rule under the principal specialization when the number of variables goes to infinity, we obtain a Markov chain of m noncolliding particles with negative drift and an absorbing wall at zero. The chain depends on the Macdonald parameters (q,t) and may be viewed as a discrete deformation of the Dyson Brownian motion. The trajectory of the Markov chain is equivalent to a certain Gibbs ensemble of plane partitions with an arbitrary cascade front wall. In the Jack limit t=qβ/2 1 the absorbing wall disappears, and the Macdonald noncolliding walks turn into the β-noncolliding random walks studied by Huang [Int. Math. Res. Not. 2021 (2021), 5898-5942, arXiv:1708.07115]. Taking q=0 (Hall-Littlewood degeneration) and further sending t 1, we obtain a continuous time particle system on Z 0 with inhomogeneous jump rates and absorbing wall at zero.