Electro-optic Modulator Based on Vanadium Dioxide Epsilon-Near- Zero Nanorods Embedded in Silicon Slot Waveguide

Gregory Tanyi; Christina Lim; Ranjith R Unnithan

doi:10.1364/CLEO_AT.2023.JTu2A.144

CLEO 2023
Technical Digest Series (Optica Publishing Group, 2023),
paper JTu2A.144
•https://doi.org/10.1364/CLEO_AT.2023.JTu2A.144

Electro-optic Modulator Based on Vanadium Dioxide Epsilon-Near- Zero Nanorods Embedded in Silicon Slot Waveguide

Gregory Tanyi, Christina Lim, and Ranjith R Unnithan

CLEO: Science and Innovations 2023

San Jose, CA United States
7–12 May 2023
ISBN: 978-1-957171-25-8

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Joint Poster Session I (JTu2A)

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G. Tanyi, C. Lim, and R. R. Unnithan, "Electro-optic Modulator Based on Vanadium Dioxide Epsilon-Near- Zero Nanorods Embedded in Silicon Slot Waveguide," in CLEO 2023, Technical Digest Series (Optica Publishing Group, 2023), paper JTu2A.144.

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Abstract

We present an electro-optic modulator exploiting a metamaterial made of an array of vanadium dioxide nanorods operating in epsilon near zero regime as the active switching material in a silicon waveguide. The modulator takes advantage of the insulator-to-metal transition of vanadium dioxide together with epsilon near zero to achieve a robust modulation depth of 20.35 dB over a broad range of wavelengths. Using simulations, we demonstrate how the effective permittivity of metamaterial can be tuned to a near-zero value by varying the nanorod geometry. The results provide insight into the design of ultra-compact epsilon-near-zero modulators with high operation frequencies and low insertion losses.

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