Design and performance analysis of all-dielectric reflective, metalens for LWIR applications

Design and performance analysis of all-dielectric reflective, metalens for LWIR applications

Abstract Reflective metalenses with multilayer substrates offer low-loss wavefront control in the LWIR range but remain underexplored and highly dependent on material choice. Here, we report a comprehensive numerical investigation into the design of LWIR reflective metalenses employing dielectric di...

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Bibliographic Details
Main Authors: Sani Mukhtar, Jaime Viegas
Format: Article
Language:English
Published: Nature Portfolio 2025-07-01
Series:Scientific Reports
Subjects:
Metasurface
Reflective metalens
Long-wave infrared (LWIR)
Focusing efficiency
Coupling effects
Material selection
Online Access:https://doi.org/10.1038/s41598-025-09823-0
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Summary:Abstract Reflective metalenses with multilayer substrates offer low-loss wavefront control in the LWIR range but remain underexplored and highly dependent on material choice. Here, we report a comprehensive numerical investigation into the design of LWIR reflective metalenses employing dielectric distributed Bragg reflectors (DBRs) substrates composed of high-index semiconductors (Si, Ge, GaAs) and zinc-based dielectric compounds (ZnO, ZnSe, ZnS). We systematically evaluate nine DBR material combinations to assess their impact on the focusing efficiency, reflectivity, and focal spot characteristics. The designed metalens, with an aperture diameter of $$\:\sim1$$ $$\:\text{m}\text{m}$$ and a focal length of 0.7 $$\text{m}\text{m}$$ , operate at a design wavelength of $$\:10.6$$ $$\:\mu\text{m}$$ . All configurations achieve high reflectance $$\:(>\:90\%)$$ over a broad spectral range, with Si/ZnSe and GaAs/ZnO based designs exhibiting the highest focusing efficiencies of $$\:\sim83.5\%$$ and $$\:\sim82.7\%,$$ respectively, at Numerical Aperture (NA) $$\:\approx\:\:0.6$$ . All the examined configurations provide nearly complete $$0-2\pi$$ phase coverage, yielding diffraction-limited focal spot sizes ranging from $$\:\:0.96\lambda\:$$ to $$\:1.02\lambda$$ . We further analyze the impact of NA and metasurface unit cell periodicity ( $$P$$ ) on the lens performance, demonstrating that smaller unit cell periods improve phase discretization and optical response uniformity, while increasing NA results in tighter focal spots, with diminishing improvements near the diffraction limit.
ISSN:2045-2322

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