Nonlinear optics in ultra-silicon-rich nitride devices: recent developments and future outlook

Dawn T. H. Tan; D. K. T. Ng; J. W. Choi; E. Sahin; B-. U. Sohn; G. F. R. Chen; P. Xing; H. Gao; Y. Cao

doi:10.1080/23746149.2021.1905544

Advances in Physics: X (Jan 2021)

Nonlinear optics in ultra-silicon-rich nitride devices: recent developments and future outlook

Dawn T. H. Tan,
D. K. T. Ng,
J. W. Choi,
E. Sahin,
B-. U. Sohn,
G. F. R. Chen,
P. Xing,
H. Gao,
Y. Cao

Affiliations

Dawn T. H. Tan: Photonics Devices and System Group, SUTD-MIT International Design Center, Singapore University of Technology and Design
D. K. T. Ng: Institute of Microelectronics, A*STAR (Agency for Science, Technology and Research)
J. W. Choi: Photonics Devices and System Group, SUTD-MIT International Design Center, Singapore University of Technology and Design
E. Sahin: Photonics Devices and System Group, SUTD-MIT International Design Center, Singapore University of Technology and Design
B-. U. Sohn: Photonics Devices and System Group, SUTD-MIT International Design Center, Singapore University of Technology and Design
G. F. R. Chen: Photonics Devices and System Group, SUTD-MIT International Design Center, Singapore University of Technology and Design
P. Xing: Photonics Devices and System Group, SUTD-MIT International Design Center, Singapore University of Technology and Design
H. Gao: Photonics Devices and System Group, SUTD-MIT International Design Center, Singapore University of Technology and Design
Y. Cao: Photonics Devices and System Group, SUTD-MIT International Design Center, Singapore University of Technology and Design

DOI: https://doi.org/10.1080/23746149.2021.1905544
Journal volume & issue: Vol. 6, no. 1

Abstract

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Nonlinear integrated optics leveraging platforms with high nonlinear figure of merit offer energy efficient optical signal processing capabilities. Over the last five years, CMOS-compatible ultra-silico-rich nitride (USRN) has emerged as a promising platform on which to implement various nonlinear optics functions. Bandgap engineered to maximize the Kerr nonlinearity while maintaining two-photon absorption free behavior at telecommunications wavelengths, USRN possesses a nonlinear refractive index that is 100× larger than that in stoichiometric silicon nitride. In this article, we review the recent progress made in USRN-based nonlinear integrated optics devices. The impacts it has made spanning from high gain optical parametric amplification and observations of soliton effects in photonic waveguides and photonic crystal waveguide structures will be discussed. Finally, we assess the future outlook of CMOS-compatible USRN-based nonlinear optics.

Published in Advances in Physics: X

ISSN: 2374-6149 (Online)
Publisher: Taylor & Francis Group
Country of publisher: United Kingdom
LCC subjects: Science: Physics
Website: https://www.tandfonline.com/journals/tapx

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