English

Directed polymers in random media under confining force

Statistical Mechanics 2009-11-11 v1

Abstract

The scaling behavior of a directed polymer in a two-dimensional (2D) random potential under confining force is investigated. The energy of a polymer with configuration {y(x)}\{y(x)\} is given by H({y(x)})=x=1N\exyx+ϵ\WaαH\big(\{y(x)\}\big) = \sum_{x=1}^N \exyx + \epsilon \Wa^\alpha, where η(x,y)\eta(x,y) is an uncorrelated random potential and \Wa\Wa is the width of the polymer. Using an energy argument, it is conjectured that the radius of gyration Rg(N)R_g(N) and the energy fluctuation ΔE(N)\Delta E(N) of the polymer of length NN in the ground state increase as Rg(N)NνR_g(N)\sim N^{\nu} and ΔE(N)Nω\Delta E(N)\sim N^\omega respectively with ν=1/(1+α)\nu = 1/(1+\alpha) and ω=(1+2α)/(4+4α)\omega = (1+2\alpha)/(4+4\alpha) for α1/2\alpha\ge 1/2. A novel algorithm of finding the exact ground state, with the effective time complexity of \cO(N3)\cO(N^3), is introduced and used to confirm the conjecture numerically.

Keywords

Cite

@article{arxiv.cond-mat/0511564,
  title  = {Directed polymers in random media under confining force},
  author = {Hyeong-Chai Jeong},
  journal= {arXiv preprint arXiv:cond-mat/0511564},
  year   = {2009}
}

Comments

9 pages, 7 figures