Asymptotic height of Plancherel random trees

Abstract

We study a natural analogue of Ulam's problem for random rooted trees distributed according to a Plancherel-type measure. This probability measure is closely related to the classical Plancherel measure on integer partitions. For a Plancherel random tree Tn with n vertices, we investigate the asymptotic behavior of its height Hn, defined as the maximal distance from the root to a leaf. We prove that this height grows logarithmically. More precisely, there is a one-parameter family of random trees (Tn(θ))n ∈ N indexed by θ>0 such that Hn n converges in probability to c(θ), where c(θ) is an explicit constant depending on the parameter θ. The case of Plancherel trees corresponds to the parameter θ=2. The proof is based on the fact that the Plancherel random trees can be viewed as Ewens fragmentation trees, for which the height exhibits a sharp threshold phenomenon. An upper bound is obtained via s-mass functionals and contraction estimates, while the lower bound is derived by embedding the model into a branching random walk with logarithmic displacements governed by a Poisson--Dirichlet distribution. The constant c(θ) is characterized through a variational principle associated with this branching random walk.