English

Nested critical points for a directed polymer on a disordered diamond lattice

Probability 2017-09-29 v2

Abstract

We consider a model for a directed polymer in a random environment defined on a hierarchical diamond lattice in which i.i.d. random variables are attached to the lattice bonds. Our focus is on scaling schemes in which a size parameter nn, counting the number of hierarchical layers of the system, becomes large as the inverse temperature β\beta vanishes. When β\beta has the form β^/n\widehat{\beta}/\sqrt{n} for a parameter β^>0\widehat{\beta}>0, we show that there is a cutoff value 0<κ<0 < \kappa < \infty such that as nn \to \infty the variance of the normalized partition function tends to zero for β^κ\widehat{\beta}\leq \kappa and grows without bound for β^>κ\widehat{\beta} > \kappa . We obtain a more refined description of the border between these two regimes by setting the inverse temperature to κ/n+αn\kappa/\sqrt{n} + \alpha_n where 0<αn1/n0 < \alpha_n \ll 1/\sqrt{n} and analyzing the asymptotic behavior of the variance. We show that when αn=α(lognloglogn)/n3/2\alpha_n = \alpha (\log n-\log \log n)/n^{3/2} (with a small modification to deal with non-zero third moment) there is a similar cutoff value η\eta for the parameter α\alpha such that when α<η\alpha < \eta the variance goes to zero and grows without bound when α>η\alpha > \eta. Extending the analysis yet again by probing around the inverse temperature κ/n+η(lognloglogn)/n3/2\kappa/\sqrt{n} + \eta (\log n-\log \log n)/n^{3/2} we find an infinite sequence of nested critical points for the variance behavior of the normalized partition function. In the subcritical cases β^κ\widehat{\beta} \leq \kappa and αη\alpha \leq \eta this analysis is extended to a central limit theorem result for the fluctuations of the normalized partition function.

Keywords

Cite

@article{arxiv.1602.06629,
  title  = {Nested critical points for a directed polymer on a disordered diamond lattice},
  author = {Tom Alberts and Jeremy Clark},
  journal= {arXiv preprint arXiv:1602.06629},
  year   = {2017}
}

Comments

21 pages; 1 figure; We made a correction to the temperature scaling and expanded our explanations in a few of the proofs

R2 v1 2026-06-22T12:54:46.309Z