In this paper, we propose a new end-to-end system for wired nano-communication networks using a self-assembled polymer. The self-assembly of a polymer creates a channel between the transmitter and the receiver in the form of a conductive nanowire that uses electrons as carriers of information. We derive the channel's analytical model and its master equation to study the dynamic process of the polymer self-assembly. We validate the analytical model with numerical and Monte-Carlo simulations. Then, we approximate the master equation by a one-dimensional Fokker-Planck equation and we solve this equation analytically and numerically. We formulate the expressions of the polymer elongation rate, its diffusion coefficient and the nullcline to study the distribution and the stability of the self-assembled nanowire. This study shows promising results for realizing stable polymer-based wired nanonetworks that can achieve high throughput.

中文翻译：

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有线纳米通信网络的物理信道模型

在本文中，我们提出了一种新的端到端系统，用于使用自组装聚合物的有线纳米通信网络。聚合物的自组装以导电纳米线的形式在发射器和接收器之间创建了一个通道，该纳米线使用电子作为信息的载体。我们推导出通道的分析模型及其主方程来研究聚合物自组装的动态过程。我们通过数值模拟和蒙特卡洛模拟验证了分析模型。然后，我们通过一维 Fokker-Planck 方程来近似主方程，并对该方程进行解析和数值求解。我们制定了聚合物伸长率、其扩散系数和零斜线的表达式，以研究自组装纳米线的分布和稳定性。