Statistics of low energy excitations for the directed polymer in a 1+d random medium (d=1,2,3)
Abstract
We consider a directed polymer of length L in a random medium of space dimension d=1,2,3. The statistics of low energy excitations as a function of their size l is numerically evaluated. These excitations can be divided into bulk and boundary excitations, with respective densities bulkL(E=0,l) and boundaryL(E=0,l). We find that both densities follow the scaling behavior bulk,boundaryL(E=0,l) = L-1-θd Rbulk,boundary(x=l/L), where θd is the exponent governing the energy fluctuations at zero temperature (with the well-known exact value θ1=1/3 in one dimension). In the limit x=l/L 0, both scaling functions Rbulk(x) and Rboundary(x) behave as Rbulk,boundary(x) x-1-θd, leading to the droplet power law bulk,boundaryL(E=0,l) l-1-θd in the regime 1 l L. Beyond their common singularity near x 0, the two scaling functions Rbulk,boundary(x) are very different : whereas Rbulk(x) decays monotonically for 0<x<1, the function Rboundary(x) first decays for 0<x<xmin, then grows for xmin<x<1, and finally presents a power law singularity Rboundary(x) (1-x)-σd near x 1. The density of excitations of length l=L accordingly decays as boundaryL(E=0,l=L) L- λd where λd=1+θd-σd. We obtain λ1 0.67, λ2 0.53 and λ3 0.39, suggesting the possible relation λd= 2 θd.
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