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Main Authors: Zhang, Tiancheng, Lei, Li, Ding, Changhao, Meng, Fanhao, Jiang, Qicheng, Li, Lijie, Dhuey, Scott, Yuan, Jingze, Cai, Zhengyan, Li, Yi, Li, Jingang, Grigoropoulos, Costas P., Tang, Haoning, Yao, Jie
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.25214
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author Zhang, Tiancheng
Lei, Li
Ding, Changhao
Meng, Fanhao
Jiang, Qicheng
Li, Lijie
Dhuey, Scott
Yuan, Jingze
Cai, Zhengyan
Li, Yi
Li, Jingang
Grigoropoulos, Costas P.
Tang, Haoning
Yao, Jie
author_facet Zhang, Tiancheng
Lei, Li
Ding, Changhao
Meng, Fanhao
Jiang, Qicheng
Li, Lijie
Dhuey, Scott
Yuan, Jingze
Cai, Zhengyan
Li, Yi
Li, Jingang
Grigoropoulos, Costas P.
Tang, Haoning
Yao, Jie
contents The orbital angular momentum (OAM) of light is a versatile degree of freedom with transformative impact across optical communication, imaging, and micromanipulation. These applications have motivated a growing demand for compact, reconfigurable vortex arrays with tunable topological charge, yet integrating these functionalities into nanophotonic platforms remains elusive. Among possible strategies to meet this challenge is exploiting the twist degree of freedom in layered structures, which enables both emerging moire physics and unprecedented reconfigurability of photonic and electronic properties. Here, we harness these capabilities in twisted bilayer moire photonic crystals (TBMPCs) to realize vortex array generation with tunable OAM, demonstrated both analytically and experimentally. Central to this advancement is a new class of quasi-bound state in the continuum: Bessel-type modes emerging from moire-induced interlayer coupling, which generate vortex beams with tailored spiral phase distributions. We experimentally demonstrate vortex beams spanning eight OAM orders, from -3 to 4, and achieve selective excitation of distinct topological charges at a fixed telecommunication wavelength by tuning the interlayer separation and twist angle. Furthermore, localized Bessel-type modes at AA stacking regions can be excited nonlocally across the moire superlattice, enabling vortex array generation. Our work offers new insights into moire physics and introduces an innovative approach for future multiplexing technology integrating OAM, wavelength, and spatial division.
format Preprint
id arxiv_https___arxiv_org_abs_2510_25214
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Moire-enabled optical vortex with tunable topological charge in twisted bilayer photonic crystals
Zhang, Tiancheng
Lei, Li
Ding, Changhao
Meng, Fanhao
Jiang, Qicheng
Li, Lijie
Dhuey, Scott
Yuan, Jingze
Cai, Zhengyan
Li, Yi
Li, Jingang
Grigoropoulos, Costas P.
Tang, Haoning
Yao, Jie
Optics
The orbital angular momentum (OAM) of light is a versatile degree of freedom with transformative impact across optical communication, imaging, and micromanipulation. These applications have motivated a growing demand for compact, reconfigurable vortex arrays with tunable topological charge, yet integrating these functionalities into nanophotonic platforms remains elusive. Among possible strategies to meet this challenge is exploiting the twist degree of freedom in layered structures, which enables both emerging moire physics and unprecedented reconfigurability of photonic and electronic properties. Here, we harness these capabilities in twisted bilayer moire photonic crystals (TBMPCs) to realize vortex array generation with tunable OAM, demonstrated both analytically and experimentally. Central to this advancement is a new class of quasi-bound state in the continuum: Bessel-type modes emerging from moire-induced interlayer coupling, which generate vortex beams with tailored spiral phase distributions. We experimentally demonstrate vortex beams spanning eight OAM orders, from -3 to 4, and achieve selective excitation of distinct topological charges at a fixed telecommunication wavelength by tuning the interlayer separation and twist angle. Furthermore, localized Bessel-type modes at AA stacking regions can be excited nonlocally across the moire superlattice, enabling vortex array generation. Our work offers new insights into moire physics and introduces an innovative approach for future multiplexing technology integrating OAM, wavelength, and spatial division.
title Moire-enabled optical vortex with tunable topological charge in twisted bilayer photonic crystals
topic Optics
url https://arxiv.org/abs/2510.25214