High-quality amorphous Silicon Carbide for hybrid photonic integration at low temperature

Integrated photonic platforms have proliferated in recent years, each demonstrating its own unique strengths and shortcomings. However, given the processing incompatibilities of different platforms, a formidable challenge in the field of integrated photonics still remains for combining the strength...

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Veröffentlicht in:	arXiv.org 2023-06
Hauptverfasser:	Lopez-Rodriguez, Bruno, Roald Van Der Kolk, Aggarwal, Samarth, Sharma, Naresh, Li, Zizheng, Van Der Plaats, Daniel, Scholte, Thomas, Chang, Jin, Pereira, Silvania F, Groeblacher, Simon, Bhaskaran, Harish, Iman Esmaeil Zadeh Zadeh
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Sprache:	eng
Schlagworte:	Amorphous materials Amorphous silicon Low temperature Optical materials Optics Photonics Platforms Refractivity Resonators Silicon carbide Thickness Waveguides
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creator	Lopez-Rodriguez, Bruno Roald Van Der Kolk Aggarwal, Samarth Sharma, Naresh Li, Zizheng Van Der Plaats, Daniel Scholte, Thomas Chang, Jin Pereira, Silvania F Groeblacher, Simon Bhaskaran, Harish Iman Esmaeil Zadeh Zadeh
description	Integrated photonic platforms have proliferated in recent years, each demonstrating its own unique strengths and shortcomings. However, given the processing incompatibilities of different platforms, a formidable challenge in the field of integrated photonics still remains for combining the strength of different optical materials in one hybrid integrated platform. Silicon carbide is a material of great interest because of its high refractive index, strong second and third-order non-linearities and broad transparecy window in the visible and near infrared. However, integrating SiC has been difficult, and current approaches rely on transfer bonding techniques, that are time consuming, expensive and lacking precision in layer thickness. Here, we demonstrate high index Amorphous Silicon Carbide (a-SiC) films deposited at 150$^{\circ}$C and verify the high performance of the platform by fabricating standard photonic waveguides and ring resonators. The intrinsic quality factors of single-mode ring resonators were in the range of $Q_{int} = (4.7-5.7)\times10^5$ corresponding to optical losses between 0.78-1.06 dB/cm. We then demonstrate the potential of this platform for future heterogeneous integration with ultralow loss thin SiN and LiNbO$_3$ platforms.
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subjects	Amorphous materials Amorphous silicon Low temperature Optical materials Optics Photonics Platforms Refractivity Resonators Silicon carbide Thickness Waveguides
title	High-quality amorphous Silicon Carbide for hybrid photonic integration at low temperature
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