Optimizing quantum transport in multi-barrier graphene systems using differential evolution
Abstract
Potential and mass barriers in graphene introduce electron scattering, modulating transmission probabilities. Complex multi-barrier setups allow electron transmission to be controlled with high precision, but have a huge design space of possible barrier geometries. This work presents a framework to optimize electronic transport in such systems using differential evolution algorithms. First, transfer matrix methods are employed to efficiently compute quantum transport through multi-barrier structures, before optimization is applied to find barrier configurations whose transmission profiles closely match a predefined target profile. To address the trade-off between the accuracy and complexity of resulting barrier configurations, regularization techniques are incorporated into the optimization process. Our approach demonstrates the potential for highly tunable electronic transport in graphene-based systems by exploiting evolution-inspired optimization techniques.
Cite
@article{arxiv.2603.07585,
title = {Optimizing quantum transport in multi-barrier graphene systems using differential evolution},
author = {Leon Browne and Stephen R. Power},
journal= {arXiv preprint arXiv:2603.07585},
year = {2026}
}
Comments
12 pages, 5 figures, under review