Second-order asymptotics for the block counting process in a class of regularly varying -coalescents

Abstract

Consider a standard -coalescent that comes down from infinity. Such a coalescent starts from a configuration consisting of infinitely many blocks at time 0, but its number of blocks Nt is a finite random variable at each positive time t. Berestycki et al. [Ann. Probab. 38 (2010) 207-233] found the first-order approximation v for the process N at small times. This is a deterministic function satisfying Nt/vt1 as t0. The present paper reports on the first progress in the study of the second-order asymptotics for N at small times. We show that, if the driving measure has a density near zero which behaves as x-β with β∈(0,1), then the process (-1/(1+β)(N t/v t-1))t0 converges in law as 0 in the Skorokhod space to a totally skewed (1+β)-stable process. Moreover, this process is a unique solution of a related stochastic differential equation of Ornstein-Uhlenbeck type, with a completely asymmetric stable L\'evy noise.