HALF-SPACE MACDONALD PROCESSES

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS

ACS Applied Bio Materials Pub Date : 2018-02-22 DOI:10.1017/FMP.2020.3

Guillaume Barraquand, A. Borodin, Ivan Corwin

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引用次数: 39

Abstract

Macdonald processes are measures on sequences of integer partitions built using the Cauchy summation identity for Macdonald symmetric functions. These measures are a useful tool to uncover the integrability of many probabilistic systems, including the Kardar–Parisi–Zhang (KPZ) equation and a number of other models in its universality class. In this paper, we develop the structural theory behind half-space variants of these models and the corresponding half-space Macdonald processes. These processes are built using a Littlewood summation identity instead of the Cauchy identity, and their analysis is considerably harder than their full-space counterparts. We compute moments and Laplace transforms of observables for general half-space Macdonald measures. Introducing new dynamics preserving this class of measures, we relate them to various stochastic processes, in particular the log-gamma polymer in a half-quadrant (they are also related to the stochastic six-vertex model in a half-quadrant and the half-space ASEP). For the polymer model, we provide explicit integral formulas for the Laplace transform of the partition function. Nonrigorous saddle-point asymptotics yield convergence of the directed polymer free energy to either the Tracy–Widom (associated to the Gaussian orthogonal or symplectic ensemble) or the Gaussian distribution depending on the average size of weights on the boundary.

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半空间麦克唐纳过程

麦克唐纳过程是利用麦克唐纳对称函数的柯西和恒等式建立的整数分区序列的度量。这些度量是揭示许多概率系统的可积性的有用工具，包括kardar - paris - zhang (KPZ)方程及其普适类中的许多其他模型。在本文中，我们发展了这些模型的半空间变体和相应的半空间麦克唐纳过程的结构理论。这些过程是用利特尔伍德和恒等式而不是柯西恒等式建立的，它们的分析比它们的全空间对应物要困难得多。我们计算了一般半空间麦克唐纳测度的可观测量的矩和拉普拉斯变换。引入新的动力学来保持这类测度，我们将它们与各种随机过程联系起来，特别是半象限中的log-gamma聚合物(它们也与半象限中的随机六顶点模型和半空间ASEP有关)。对于聚合物模型，我们给出了配分函数拉普拉斯变换的显式积分公式。非严格鞍点渐近导致定向聚合物自由能收敛于Tracy-Widom(与高斯正交或辛系综相关)或高斯分布，这取决于边界上权值的平均大小。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

ACS Applied Bio Materials Chemistry-Chemistry (all)

CiteScore

9.40

自引率

2.10%

发文量

464