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Main Author: Bobowski, Jake S.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2601.01381
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author Bobowski, Jake S.
author_facet Bobowski, Jake S.
contents We present two complementary simulations that lead to an exploration of Anderson localization, a phenomenon in which wave diffusion is suppressed in disordered media by interference from multiple scattering. To build intuition, the first models the random walk of classical, non-interacting point-like particles, providing a clear analogy to the way disorder can limit transport. The second examines the propagation of an electromagnetic pulse through a one-dimensional, lossless transmission line with randomly varying propagation constant and characteristic impedance along its length, a system that captures the interference effects essential for true Anderson localization. We evaluate quantitative measures that reveal the transition from normal diffusion to localization of particles in one case, and the exponential confinement of wave energy in the other. Together, these simulations offer a pair of accessible tools for investigating localization phenomena in an instructional setting.
format Preprint
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institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Simulating diffusion and disorder-induced localization in random walks and transmission lines
Bobowski, Jake S.
Disordered Systems and Neural Networks
Physics Education
We present two complementary simulations that lead to an exploration of Anderson localization, a phenomenon in which wave diffusion is suppressed in disordered media by interference from multiple scattering. To build intuition, the first models the random walk of classical, non-interacting point-like particles, providing a clear analogy to the way disorder can limit transport. The second examines the propagation of an electromagnetic pulse through a one-dimensional, lossless transmission line with randomly varying propagation constant and characteristic impedance along its length, a system that captures the interference effects essential for true Anderson localization. We evaluate quantitative measures that reveal the transition from normal diffusion to localization of particles in one case, and the exponential confinement of wave energy in the other. Together, these simulations offer a pair of accessible tools for investigating localization phenomena in an instructional setting.
title Simulating diffusion and disorder-induced localization in random walks and transmission lines
topic Disordered Systems and Neural Networks
Physics Education
url https://arxiv.org/abs/2601.01381