Skew column RSK dynamics and the box-ball system

Abstract

The Fomin local rules for Schensted column insertion can be seen as a two-lane box-ball system, in which a carrier moves particles forward or laterally. Running such two-lane dynamics in parallel on a periodic lattice gives rise to a two-dimensional generalization of the box-ball system, which we call the skew column RSK dynamics. Equivalently, this is a deterministic dynamics on pairs of skew semistandard Young tableaux (Pt,Qt)t ∈ Z. We prove that this dynamics exhibits solitonic behavior and construct an explicit bijection (P,Q) (H1,H2,κ,ν) that linearizes the time evolution. The resulting coordinates consist of two horizontally weak tableaux H1,H2 recording the asymptotic soliton data, integer riggings κ, and a weakly decreasing sequence of integers ν. A key feature of the construction is an explicit projection from the skew column RSK dynamics to the classical box-ball system; under this projection, the rigging κ is precisely the Kerov--Kirillov--Reshetikhin rigging of the associated box-ball configuration. Our proof uses two commuting affine crystal structures on pairs of skew tableaux and a novel connectivity theorem for distinguished subgraphs of tensor products of Kirillov--Reshetikhin crystals. We also derive Greene-type formulas for the soliton lengths in terms of last-passage percolation on the associated cylindrical environment. Finally, by taking generating functions in the linearizing coordinates, we obtain bijective proofs of Cauchy and Kawanaka--Littlewood-type identities for transformed Hall--Littlewood polynomials.