Coupling-controlled Dual ITO Layer Electro-Optic Modulator in Silicon Photonics
Mohammad H. Tahersima, Zhizhen Ma, Yaliang Gui, Mario Miscuglio, Shuai, Sun, Rubab Amin, Hamed Dalir, Volker J. Sorger

TL;DR
This paper introduces a compact silicon photonic electro-optic modulator using a heterogeneously integrated dual-gated ITO phase shifter at the microring-bus coupler, achieving high modulation efficiency and low loss.
Contribution
It presents the first coupling-controlled electro-optic modulator with heterogeneously integrated ITO, overcoming silicon's weak electro-optic response and enabling high-density photonic integration.
Findings
Achieved 4 dB extinction ratio on resonance
Demonstrated 1.5 dB off-resonance with low 0.15 dB insertion loss
Device size of only 4 micrometers
Abstract
Electro-optic signal modulation provides a key functionality in modern technology and information networks. Photonic integration has enabled not only miniaturizing photonic components, but also provided performance improvements due to co-design addressing both electrical and optical device rules. However the millimeter-to-centimeter large footprint of many foundry-ready photonic electro-optic modulators significantly limits scaling density. Furthermore, modulators bear a fundamental a frequency-response to energy-sensitive trade-off, a limitation that can be overcome with coupling-based modulators where the temporal response speed is decoupled from the optical cavity photo lifetime. Thus, the coupling effect to the resonator is modulated rather then tuning the index of the resonator itself. However, the weak electro-optic response of silicon limits such coupling modulator performance,…
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Taxonomy
TopicsPhotonic and Optical Devices · Neural Networks and Reservoir Computing · Optical Network Technologies
