Driven Lorentz model in discrete time

arXiv - PHYS - Statistical Mechanics Pub Date : 2024-09-04 DOI:arxiv-2409.02696

Dan Shafir, Alessio Squarcini, Stanislav Burov, Thomas Franosch

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Abstract

We consider a tracer particle performing a random walk on a two-dimensional lattice in the presence of immobile hard obstacles. Starting from equilibrium, a constant force pulling on the particle is switched on, driving the system to a new stationary state. Our study calculates displacement moments in discrete time (number of steps $N$) for an arbitrarily strong constant driving force, exact to first order in obstacle density. We find that for fixed driving force $F$, the approach to the terminal discrete velocity scales as $\sim N^{-1} \exp(- N F^2 / 16)$ for small $F$, differing significantly from the $\sim N^{-1}$ prediction of linear response. Besides a non-analytic dependence on the force and breakdown of Einstein's linear response, our results show that fluctuations in the directions of the force are enhanced in the presence of obstacles. Notably, the variance grows as $\sim N^3$ (superdiffusion) for $F \to \infty$ at intermediate steps, reverting to normal diffusion ($\sim N$) at larger steps, a behavior previously observed in continuous time but demonstrated here in discrete steps for the first time. Unlike the exponential waiting time case, the superdiffusion regime starts immediately at $N=1$. The framework presented allows considering any type of waiting-time distribution between steps and transition to continuous time using subordination methods. Our findings are also validated through computer simulations.

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离散时间中的驱动洛伦兹模型

我们考虑的是一个示踪粒子在二维网格上进行随机行走时遇到的不动硬障碍物。从平衡状态开始，粒子受到一个恒定力的牵引，驱动系统进入一个新的静止状态。我们的研究计算了任意强恒定驱动力在离散时间（步数 $N$）内的位移矩，精确到障碍物密度的一阶。我们发现，对于固定的驱动力$F$，在小$F$的情况下，接近终端离散速度的尺度为$\sim N^{-1}\exp(- N F^2 / 16)$，这与线性响应的预测值$\simN^{-1}$有很大不同。除了对力的非解析依赖和爱因斯坦线性响应的破坏之外，我们的结果还表明，在存在障碍物的情况下，力的方向波动会增强。值得注意的是，在中间步长的$F\to \infty$中，方差以$\sim N^3$（超扩散）的形式增长，而在更大的步长中则恢复为正常扩散（$\sim N$），这种行为以前在连续时间中观察到过，但在这里首次在离散步长中得到了证明。与指数等待时间的情况不同，超扩散机制在 $N=1$ 时立即开始。我们提出的框架允许考虑步长之间任何类型的等待时间分布，并使用从属方法过渡到连续时间。

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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arXiv - PHYS - Statistical Mechanics

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