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Autores principales: White, Simon J. U., Bernal-García, Diego N., Tran, Toan Trong, Aharonovich, Igor, Solntsev, Alexander S.
Formato: Preprint
Publicado: 2026
Materias:
Acceso en línea:https://arxiv.org/abs/2605.03251
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author White, Simon J. U.
Bernal-García, Diego N.
Tran, Toan Trong
Aharonovich, Igor
Solntsev, Alexander S.
author_facet White, Simon J. U.
Bernal-García, Diego N.
Tran, Toan Trong
Aharonovich, Igor
Solntsev, Alexander S.
contents Anderson localization of light is a fundamental emergent phenomenon in disordered systems. In arrays of coupled waveguides, it suppresses transport and causes photons to remain localized near the excitation site as coupling disorder increases. Here, we experimentally demonstrate Anderson localization using single photons emitted by a single-photon emitter in hexagonal boron nitride at room temperature. Despite the limited temporal coherence of the emitter, the photons undergo pronounced Anderson localization, evidenced by exponentially localized output intensity profiles in disordered waveguide lattices. Beyond the experimental demonstration, we develop a general theoretical framework for wave propagation in disordered tight-binding systems, showing that the configuration-averaged output intensity converges to a stationary spatial distribution at large propagation distances. In the case of off-diagonal disorder, this stationary profile is characterized by an effective localization length that exhibits a robust inverse-variance scaling with the disorder strength. These results establish defect-based room-temperature emitters as practical platforms for studying Anderson localization in integrated photonics and support their use in applications that exploit controlled disorder, including neuromorphic and quantum photonic architectures.
format Preprint
id arxiv_https___arxiv_org_abs_2605_03251
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Anderson Localization with Single Photons from a Quantum Emitter
White, Simon J. U.
Bernal-García, Diego N.
Tran, Toan Trong
Aharonovich, Igor
Solntsev, Alexander S.
Optics
Anderson localization of light is a fundamental emergent phenomenon in disordered systems. In arrays of coupled waveguides, it suppresses transport and causes photons to remain localized near the excitation site as coupling disorder increases. Here, we experimentally demonstrate Anderson localization using single photons emitted by a single-photon emitter in hexagonal boron nitride at room temperature. Despite the limited temporal coherence of the emitter, the photons undergo pronounced Anderson localization, evidenced by exponentially localized output intensity profiles in disordered waveguide lattices. Beyond the experimental demonstration, we develop a general theoretical framework for wave propagation in disordered tight-binding systems, showing that the configuration-averaged output intensity converges to a stationary spatial distribution at large propagation distances. In the case of off-diagonal disorder, this stationary profile is characterized by an effective localization length that exhibits a robust inverse-variance scaling with the disorder strength. These results establish defect-based room-temperature emitters as practical platforms for studying Anderson localization in integrated photonics and support their use in applications that exploit controlled disorder, including neuromorphic and quantum photonic architectures.
title Anderson Localization with Single Photons from a Quantum Emitter
topic Optics
url https://arxiv.org/abs/2605.03251