Participation ratio for constraint-driven condensation with superextensive mass

Abstract

Broadly distributed random variables with a power-law distribution f(m) m-(1+α) are known to generate condensation effects, in the sense that, when the exponent α lies in a certain interval, the largest variable in a sum of N (independent and identically distributed) terms is for large N of the same order as the sum itself. In particular, when the distribution has infinite mean (0<α<1) one finds unconstrained condensation, whereas for α>1 constrained condensation takes places fixing the total mass to a large enough value M=Σi=1N mi > Mc. In both cases, a standard indicator of the condensation phenomenon is the participation ratio Yk= Σi mik / (Σi mi)k (k>1), which takes a finite value for N ∞ when condensation occurs. To better understand the connection between constrained and unconstrained condensation, we study here the situation when the total mass is fixed to a superextensive value M N1+δ (δ >0), hence interpolating between the unconstrained condensation case (where the typical value of the total mass scales as M N1/α for α<1) and the extensive constrained mass. In particular we show that for exponents α<1 a condensate phase for values δ > δc=1/α-1 is separated from a homogeneous phase at δ < δc by a transition line, δ=δc, where a weak condensation phenomenon takes place. We focus on the evaluation of the participation ratio as a generic indicator of condensation, also recalling or presenting results in the standard cases of unconstrained mass and of fixed extensive mass.