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Hauptverfasser: Seegert, Kristian, Gajardo, Roberto, Huyet, Guillaume, Raineri, Fabrice, Madiot, Guilhem
Format: Preprint
Veröffentlicht: 2026
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Online-Zugang:https://arxiv.org/abs/2604.08487
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author Seegert, Kristian
Gajardo, Roberto
Huyet, Guillaume
Raineri, Fabrice
Madiot, Guilhem
author_facet Seegert, Kristian
Gajardo, Roberto
Huyet, Guillaume
Raineri, Fabrice
Madiot, Guilhem
contents Non-Hermitian photonics provides a framework to engineer the gain and loss of optical modes in open systems, enabling control of their spectral and dynamical properties. In particular, the ability to dynamically tune modal losses offers a route to implement functionalities traditionally relying on cavity Q-factor modulation, such as Q-switching, within nanophotonic platforms. Here, we demonstrate the generation of short optical pulses in a pair of phase-coupled photonic crystal nanolasers exploiting non-Hermitian coupling. Two waveguide-coupled nanocavities are operated below their individual lasing thresholds and subjected to asymmetric optical pumping, such that a transient carrier-induced detuning modifies the interference conditions between them. This dynamically controls the gain and loss of the collective modes, and, upon crossing a resonance condition, leads to the rapid release of stored carrier energy as an optical pulse. A rate-equation model captures the interplay between carrier dynamics and modal coupling and reproduces the observed behavior. Experiments performed on an indium phosphide platform show pulse generation from cavities that do not lase efficiently on their own in continuous-wave operation, with temporal characteristics governed by carrier dynamics. These results indicate that non-Hermitian coupling can be used to control the effective cavity losses in time, providing a route to pulse generation in integrated photonic systems.
format Preprint
id arxiv_https___arxiv_org_abs_2604_08487
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Dynamical control of non-hermitian coupling between sub-threshold nanolasers enables Q-switched pulse generation
Seegert, Kristian
Gajardo, Roberto
Huyet, Guillaume
Raineri, Fabrice
Madiot, Guilhem
Optics
Mesoscale and Nanoscale Physics
Non-Hermitian photonics provides a framework to engineer the gain and loss of optical modes in open systems, enabling control of their spectral and dynamical properties. In particular, the ability to dynamically tune modal losses offers a route to implement functionalities traditionally relying on cavity Q-factor modulation, such as Q-switching, within nanophotonic platforms. Here, we demonstrate the generation of short optical pulses in a pair of phase-coupled photonic crystal nanolasers exploiting non-Hermitian coupling. Two waveguide-coupled nanocavities are operated below their individual lasing thresholds and subjected to asymmetric optical pumping, such that a transient carrier-induced detuning modifies the interference conditions between them. This dynamically controls the gain and loss of the collective modes, and, upon crossing a resonance condition, leads to the rapid release of stored carrier energy as an optical pulse. A rate-equation model captures the interplay between carrier dynamics and modal coupling and reproduces the observed behavior. Experiments performed on an indium phosphide platform show pulse generation from cavities that do not lase efficiently on their own in continuous-wave operation, with temporal characteristics governed by carrier dynamics. These results indicate that non-Hermitian coupling can be used to control the effective cavity losses in time, providing a route to pulse generation in integrated photonic systems.
title Dynamical control of non-hermitian coupling between sub-threshold nanolasers enables Q-switched pulse generation
topic Optics
Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2604.08487