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Main Authors: Liu, Qian, Xia, Xiaoshuang, Wang, Junjie, Hong, Peilong, Xu, Lei, Huang, Lujun, Song, Daohong, Liang, Yi
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.20272
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author Liu, Qian
Xia, Xiaoshuang
Wang, Junjie
Hong, Peilong
Xu, Lei
Huang, Lujun
Song, Daohong
Liang, Yi
author_facet Liu, Qian
Xia, Xiaoshuang
Wang, Junjie
Hong, Peilong
Xu, Lei
Huang, Lujun
Song, Daohong
Liang, Yi
contents Disorder in moire superlattices simultaneously degrades flat-band localization and induces Anderson localization, yet how these two regimes interact has remained unclear. Here, we introduce a combined framework linking localization-length scaling with differential probability density analysis to map localization transitions in partially disordered one-dimensional silicon moire lattices. It is found that flat bands confined within the interband gap keep their strong localization even as disorder grows. In contrast, flat bands intersecting dispersive bands exhibit rich behaviors: the low-frequency branch undergoes an inverse Anderson transition, while the high-frequency branch supports coexisting flat-band and Anderson localization at strong disorder. Our results deliver the direct evidence of competing localization mechanisms in disordered moire systems and offer guiding principles for engineering robust, nonideal moire photonic devices.
format Preprint
id arxiv_https___arxiv_org_abs_2604_20272
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Interplay of Flat-band and Anderson localizations in disordered moire superlattices
Liu, Qian
Xia, Xiaoshuang
Wang, Junjie
Hong, Peilong
Xu, Lei
Huang, Lujun
Song, Daohong
Liang, Yi
Disordered Systems and Neural Networks
Optics
Disorder in moire superlattices simultaneously degrades flat-band localization and induces Anderson localization, yet how these two regimes interact has remained unclear. Here, we introduce a combined framework linking localization-length scaling with differential probability density analysis to map localization transitions in partially disordered one-dimensional silicon moire lattices. It is found that flat bands confined within the interband gap keep their strong localization even as disorder grows. In contrast, flat bands intersecting dispersive bands exhibit rich behaviors: the low-frequency branch undergoes an inverse Anderson transition, while the high-frequency branch supports coexisting flat-band and Anderson localization at strong disorder. Our results deliver the direct evidence of competing localization mechanisms in disordered moire systems and offer guiding principles for engineering robust, nonideal moire photonic devices.
title Interplay of Flat-band and Anderson localizations in disordered moire superlattices
topic Disordered Systems and Neural Networks
Optics
url https://arxiv.org/abs/2604.20272