Scaling limit of 1+1 dimensional directed polymer with power-law tail and spatial correlated noise
Abstract
We study a (1+1)-dimensional directed polymer in a spatially correlated random environment generated by power-law tail variables: ω(i,x)=Σy∈ Zψy-xξ(i,y), ψy λr |y|-r, r∈(1/2,1), where the variables ξ(i,y) are i.i.d. and have a regularly varying right tail with exponent α>2. The spatial covariance of the environment has long-range decay with Hurst parameter H=32-r∈(1/2,1). We identify the limiting fluctuations of the log-partition function in the intermediate disorder regime and show that the critical tail exponent is αc=3H=63-2r. When α>αc, the model has the same scaling limits as the corresponding Gaussian spatially correlated polymer: if βNNH/2β∈(0,∞), the centered log-partition function converges to the logarithm of the solution of the stochastic heat equation driven by fractional spatial noise; if βNNH/20, its normalized fluctuation converges to a centered Gaussian law. In the regime 2<ααc, at the scale βNNH/2=βNH/2/l(N3/2), the log-partition function still satisfies Gaussian fluctuation. The main ingredient is a truncation comparison argument adapted to long-range moving-average environments, together with an invariance principle for polynomial chaos. Due to the non-locality of the environments, we perform a far-near field analysis, as well as multiscale analysis, to prove that the truncated version does not change the log-partition function at the corresponding scales.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.