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Main Authors: Kraus, Eleonora P., Fitzgerald, Jamie M., Maciel-Escudero, Carlos, Malic, Ermin
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.12779
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author Kraus, Eleonora P.
Fitzgerald, Jamie M.
Maciel-Escudero, Carlos
Malic, Ermin
author_facet Kraus, Eleonora P.
Fitzgerald, Jamie M.
Maciel-Escudero, Carlos
Malic, Ermin
contents Sub-wavelength thick photonic crystal (PhC) slabs coupled to 2D excitonic materials, such as transition metal dichalcogenides (TMDs), are a promising platform for highly tunable, room-temperature, on-chip optoelectronic devices. Unlike conventional Fabry-Perot microcavities, these compact open cavities exhibit non-trivial electric field profiles, leading to spatially distinct regions of weak and strong coupling with excitons within the PhC unit cell. Using coupled mode theory and rigorous solutions to Maxwell's equations, we investigate how the PhC geometry can be used to control these coexisting exciton/polariton contributions and tailor the resulting optical spectra. For large filling factors, i.e., small air gaps, we show that PhC polaritons can be modeled as dark waveguide modes brightened via the periodicity of the PhC slab. Furthermore, by spatially patterning the TMD monolayer based on the local field intensity, we reveal the simultaneous presence of excitons in both the weak and strong coupling regimes. Overall, this work provides fundamental insights into the strong light-matter coupling regime in structured photonic environments, offering a pathway to design and optimize metal-free, ultra-compact polaritonic devices.
format Preprint
id arxiv_https___arxiv_org_abs_2604_12779
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Engineering strong coupling in ultra-compact photonic crystal/2D material platforms
Kraus, Eleonora P.
Fitzgerald, Jamie M.
Maciel-Escudero, Carlos
Malic, Ermin
Optics
Mesoscale and Nanoscale Physics
Sub-wavelength thick photonic crystal (PhC) slabs coupled to 2D excitonic materials, such as transition metal dichalcogenides (TMDs), are a promising platform for highly tunable, room-temperature, on-chip optoelectronic devices. Unlike conventional Fabry-Perot microcavities, these compact open cavities exhibit non-trivial electric field profiles, leading to spatially distinct regions of weak and strong coupling with excitons within the PhC unit cell. Using coupled mode theory and rigorous solutions to Maxwell's equations, we investigate how the PhC geometry can be used to control these coexisting exciton/polariton contributions and tailor the resulting optical spectra. For large filling factors, i.e., small air gaps, we show that PhC polaritons can be modeled as dark waveguide modes brightened via the periodicity of the PhC slab. Furthermore, by spatially patterning the TMD monolayer based on the local field intensity, we reveal the simultaneous presence of excitons in both the weak and strong coupling regimes. Overall, this work provides fundamental insights into the strong light-matter coupling regime in structured photonic environments, offering a pathway to design and optimize metal-free, ultra-compact polaritonic devices.
title Engineering strong coupling in ultra-compact photonic crystal/2D material platforms
topic Optics
Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2604.12779