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Designing fast and efficient electrically driven phase change photonics using foundry compatible waveguide-integrated microheaters

John R. Erickson, Vivswan Shah, Qingzhou Wan, Nathan Youngblood, Feng Xiong

2022Optics Express32 citationsDOIOpen Access PDF

Abstract

(GST) have recently enabled advanced optical devices for applications such as in-memory computing, reflective displays, tunable metasurfaces, and reconfigurable photonics. However, designing phase change optical devices with reliable and efficient electrical control is challenging due to the requirements of both high amorphization temperatures and extremely fast quenching rates for reversible switching. Here, we use a Multiphysics simulation framework to model three waveguide-integrated microheaters designed to switch optical phase change materials. We explore the effects of geometry, doping, and electrical pulse parameters to optimize the switching speed and minimize energy consumption in these optical devices.

Topics & Concepts

Materials sciencePhotonicsMultiphysicsOptical switchOptoelectronicsWaveguideMicroheaterNanophotonicsPhase changeOpticsPhase-change materialComputer scienceFabricationEngineering physicsFinite element methodPhysicsAlternative medicineThermodynamicsMedicinePathologyPhase-change materials and chalcogenidesPhotonic and Optical DevicesNeural Networks and Reservoir Computing
Designing fast and efficient electrically driven phase change photonics using foundry compatible waveguide-integrated microheaters | Litcius