KPZ exponents for the half-space log-gamma polymer
Abstract
We consider the point-to-point log-gamma polymer of length 2N in a half-space with i.i.d. Gamma-1(2θ) distributed bulk weights and i.i.d. Gamma-1(α+θ) distributed boundary weights for θ>0 and α>-θ. We establish the KPZ exponents (1/3 fluctuation and 2/3 transversal) for this model when α=N-1/3μ for μ∈ R fixed (critical regime) and when α>0 is fixed (supercritical regime). In particular, in these two regimes, we show that after appropriate centering, the free energy process with spatial coordinate scaled by N2/3 and fluctuations scaled by N1/3 is tight. These regimes correspond to a polymer measure which is not pinned at the boundary. This is the first instance of establishing the 2/3 transversal exponent for a positive temperature half-space model, and the first instance of the 1/3 fluctuation exponent besides precisely at the boundary where recent work of arXiv:2204.08420 applies and also gives the exact one-point fluctuation distribution (our methods do not access exact fluctuation distributions). Our proof relies on two inputs -- the relationship between the half-space log-gamma polymer and half-space Whittaker process (facilitated by the geometric RSK correspondence as initiated in arXiv:1110.3489, arXiv:1210.5126), and an identity in arXiv:2108.08737 which relates the point-to-line half-space partition function to the full-space partition function for the log-gamma polymer. The primary technical contribution of our work is to construct the half-space log-gamma Gibbsian line ensemble and develop, in the spirit of work initiated in arXiv:1108.2291, a toolbox for extracting tightness and absolute continuity results from minimal information about the top curve of such half-space line ensembles. This is the first study of half-space line ensembles.
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