The development of plasmonics and related applications in the terahertz range faces limitations due to the intrinsic high electron density of the standard metals. All-dielectric systems are profitable alternatives, which allows for customized modulation of the optical response upon doping. Here, plasmon-based hyperbolic metamaterials are realized stacking doped III-V semiconductors that have been shown to be optically active in the terahertz spectral region. By using a multi-physics multi-scale theoretical approach, the role of doping and geometrical characteristics (e.g., thickness, composition, grating) in the modulation of high-k plasmon-polariton modes across the metamaterial is unraveled.
Terahertz Volume Plasmon‐Polariton Modulation in All‐Dielectric Hyperbolic Metamaterials
Luca Bursi
;Arrigo Calzolari
2026
Abstract
The development of plasmonics and related applications in the terahertz range faces limitations due to the intrinsic high electron density of the standard metals. All-dielectric systems are profitable alternatives, which allows for customized modulation of the optical response upon doping. Here, plasmon-based hyperbolic metamaterials are realized stacking doped III-V semiconductors that have been shown to be optically active in the terahertz spectral region. By using a multi-physics multi-scale theoretical approach, the role of doping and geometrical characteristics (e.g., thickness, composition, grating) in the modulation of high-k plasmon-polariton modes across the metamaterial is unraveled.| File | Dimensione | Formato | |
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Advanced Optical Materials - 2026 - Campanaro - Terahertz Volume Plasmon‐Polariton Modulation in All‐Dielectric Hyperbolic.pdf
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