Thermal metasurface with tunable narrowband absorption from a hybrid graphene/silicon photonic crystal resonance | Zendy

Arun Nagpal | Zendy; Ming Zhou | Zendy; Ognjen Ilic | Zendy; Zongfu Yu | Zendy; Harry A. Atwater | Zendy

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Thermal metasurface with tunable narrowband absorption from a hybrid graphene/silicon photonic crystal resonance

Author(s) -

Arun Nagpal,

Ming Zhou,

Ognjen Ilic,

Zongfu Yu,

Harry A. Atwater

Publication year - 2022

Publication title -

optics express

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 1.394

H-Index - 271

ISSN - 1094-4087

DOI - 10.1364/oe.470198

Subject(s) - materials science , narrowband , optics , photonic crystal , optoelectronics , graphene , silicon , resonance (particle physics) , absorption (acoustics) , guided mode resonance , negative refraction , refractive index , fano resonance , diffraction grating , plasmon , nanotechnology , physics , wavelength , particle physics

We report the design of a tunable, narrowband, thermal metasurface that employs a hybrid resonance generated by coupling a tunable permittivity graphene ribbon to a silicon photonic crystal. The gated graphene ribbon array, proximitized to a high quality factor Si photonic crystal supporting a guided mode resonance, exhibits tunable narrowband absorbance lineshapes (Q > 10,000). Actively tuned Fermi level modulation in graphene with applied gate voltage between high absorptivity and low absorptivity states gives rise to absorbance on/off ratios exceeding 60. We employ coupled-mode theory as a computationally efficient approach to elements of the metasurface design, demonstrating an orders of magnitude speedup over typical finite element computational methods.

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