Ultracompact (3 μm) Silicon Slow-light Optical Modulator

Overview

Journal Sci Rep

Specialty Science

Date 2013 Dec 19

PMID 24346067

Citations 1

Authors

Aron Opheij

Nir Rotenberg

Daryl M Beggs

Isabella H Rey

Thomas F Krauss

L Kuipers

Affiliations

Soon will be listed here.

Abstract

Wavelength-scale optical modulators are essential building blocks for future on-chip optical interconnects. Any modulator design is a trade-off between bandwidth, size and fabrication complexity, size being particularly important as it determines capacitance and actuation energy. Here, we demonstrate an interesting alternative that is only 3 μm long, only uses silicon on insulator (SOI) material and accommodates several nanometres of optical bandwidth at 1550 nm. The device is based on a photonic crystal waveguide: by combining the refractive index shift with slow-light enhanced absorption induced by free-carrier injection, we achieve an operation bandwidth that significantly exceeds the shift of the bandedge. We compare a 3 μm and an 80 μm long modulator and surprisingly, the shorter device outperforms the longer one. Despite its small size, the device achieves an optical bandwidth as broad as 7 nm for an extinction ratio of 10 dB, and modulation times ranging between 500 ps and 100 ps.

Citing Articles

Recent Progress in Silicon-Based Slow-Light Electro-Optic Modulators.

Han C, Jin M, Tao Y, Shen B, Wang X Micromachines (Basel). 2022; 13(3).

PMID: 35334692 PMC: 8950839. DOI: 10.3390/mi13030400.

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