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Main Authors: Milibaeva, G. M., Yusupov, H. T., Berdiyorova, D. G., Rakhimova, Y., Yusupov, M., Chaves, A., Rakhimov, Kh.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.01102
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author Milibaeva, G. M.
Yusupov, H. T.
Berdiyorova, D. G.
Rakhimova, Y.
Yusupov, M.
Chaves, A.
Rakhimov, Kh.
author_facet Milibaeva, G. M.
Yusupov, H. T.
Berdiyorova, D. G.
Rakhimova, Y.
Yusupov, M.
Chaves, A.
Rakhimov, Kh.
contents In this study, using the Dirac continuum model combined with the split-operator technique, we investigate the propagation dynamics of wave packets in graphene in the presence of circular potential barriers arranged in square and triangular geometries. Our results reveal a non-monotonic dependence of the wave packet transmission on the number of barrier rows along the propagation direction: the transmission initially decreases as rows of barriers are removed, but then increases again when additional rows are eliminated. To explain the observed nonlinear behavior, the time evolution of the transmission probability is analyzed, providing insight into the interplay between wave packet dynamics and the spatial arrangement of potential barriers. These findings offer a pathway for designing graphene-based devices with tunable transport properties through engineered potential landscapes.
format Preprint
id arxiv_https___arxiv_org_abs_2510_01102
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Wave Packet Propagation through Graphene with Square and Triangular Patterned Circular Potential Scatterers
Milibaeva, G. M.
Yusupov, H. T.
Berdiyorova, D. G.
Rakhimova, Y.
Yusupov, M.
Chaves, A.
Rakhimov, Kh.
Mesoscale and Nanoscale Physics
In this study, using the Dirac continuum model combined with the split-operator technique, we investigate the propagation dynamics of wave packets in graphene in the presence of circular potential barriers arranged in square and triangular geometries. Our results reveal a non-monotonic dependence of the wave packet transmission on the number of barrier rows along the propagation direction: the transmission initially decreases as rows of barriers are removed, but then increases again when additional rows are eliminated. To explain the observed nonlinear behavior, the time evolution of the transmission probability is analyzed, providing insight into the interplay between wave packet dynamics and the spatial arrangement of potential barriers. These findings offer a pathway for designing graphene-based devices with tunable transport properties through engineered potential landscapes.
title Wave Packet Propagation through Graphene with Square and Triangular Patterned Circular Potential Scatterers
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2510.01102