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Main Authors: Bahsoun, Mohamad, Groenen, Jesse, Agez, Gonzague, Joulié, Sébastien, Marcelot, Cécile, Cours, Robin, Kerdiles, Sébastien, Opprecht, Mathieu, Bonafos, Caroline, Poumirol, Jean-Marie
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.04854
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author Bahsoun, Mohamad
Groenen, Jesse
Agez, Gonzague
Joulié, Sébastien
Marcelot, Cécile
Cours, Robin
Kerdiles, Sébastien
Opprecht, Mathieu
Bonafos, Caroline
Poumirol, Jean-Marie
author_facet Bahsoun, Mohamad
Groenen, Jesse
Agez, Gonzague
Joulié, Sébastien
Marcelot, Cécile
Cours, Robin
Kerdiles, Sébastien
Opprecht, Mathieu
Bonafos, Caroline
Poumirol, Jean-Marie
contents The ability to engineer localized surface plasmon resonances at large scale usually relies on precise nanoscale patterning. Here, we demonstrate that mid-infrared plasmonic responses can instead emerge in unpatterned polysilicon films composed of nanometric (5-50 nm) grains, challenging established design paradigms and eliminating the need for external nanostructuring. Using tailored out-of-equilibrium annealing conditions, we show that hyperdoped polysilicon layers exhibit enhanced light-matter interactions that can be tuned across the mid-infrared range. By combining advanced electron microscopy, infrared spectroscopy and finite-difference time-domain electrodynamic simulations, we demonstrate that these remarkable optical properties originate from naturally formed metal-dielectric interfaces at grain boundaries, which support localized surface plasmon resonances. Importantly, this result is universal and can be extended to any doped semiconductor system, regardless of the synthesis technique, provided that the grain size remains in the nanometric range. This work opens up a new field in plasmonics centered on polycrystalline semiconductors, paving the way for cost-effective systems that are fully compatible with microelectronic and photovoltaic technologies, and capable of significantly reshaping light-matter interactions in the infrared range.
format Preprint
id arxiv_https___arxiv_org_abs_2605_04854
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Emergence of Localized Surface Plasmons in Unpatterned Hyperdoped Polycrystalline Silicon
Bahsoun, Mohamad
Groenen, Jesse
Agez, Gonzague
Joulié, Sébastien
Marcelot, Cécile
Cours, Robin
Kerdiles, Sébastien
Opprecht, Mathieu
Bonafos, Caroline
Poumirol, Jean-Marie
Optics
Materials Science
The ability to engineer localized surface plasmon resonances at large scale usually relies on precise nanoscale patterning. Here, we demonstrate that mid-infrared plasmonic responses can instead emerge in unpatterned polysilicon films composed of nanometric (5-50 nm) grains, challenging established design paradigms and eliminating the need for external nanostructuring. Using tailored out-of-equilibrium annealing conditions, we show that hyperdoped polysilicon layers exhibit enhanced light-matter interactions that can be tuned across the mid-infrared range. By combining advanced electron microscopy, infrared spectroscopy and finite-difference time-domain electrodynamic simulations, we demonstrate that these remarkable optical properties originate from naturally formed metal-dielectric interfaces at grain boundaries, which support localized surface plasmon resonances. Importantly, this result is universal and can be extended to any doped semiconductor system, regardless of the synthesis technique, provided that the grain size remains in the nanometric range. This work opens up a new field in plasmonics centered on polycrystalline semiconductors, paving the way for cost-effective systems that are fully compatible with microelectronic and photovoltaic technologies, and capable of significantly reshaping light-matter interactions in the infrared range.
title Emergence of Localized Surface Plasmons in Unpatterned Hyperdoped Polycrystalline Silicon
topic Optics
Materials Science
url https://arxiv.org/abs/2605.04854