Low-power variable optical attenuator based on a hybrid SiON–polymer S-bend waveguide

Lingfang Wang; Qianqian Song; Jieyun Wu; Kaixin Chen

doi:10.1364/AO.55.000969

Applied Optics
Vol. 55,
Issue 5,
pp. 969-973
(2016)
•https://doi.org/10.1364/AO.55.000969

Low-power variable optical attenuator based on a hybrid SiON–polymer S-bend waveguide

Lingfang Wang, Qianqian Song, Jieyun Wu, and Kaixin Chen

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Lingfang Wang, Qianqian Song, Jieyun Wu, and Kaixin Chen, "Low-power variable optical attenuator based on a hybrid SiON–polymer S-bend waveguide," Appl. Opt. 55, 969-973 (2016)

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- Integrated Optics Devices
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About this Article
History
- Original Manuscript: November 18, 2015
- Revised Manuscript: January 2, 2016
- Manuscript Accepted: January 4, 2016
- Published: February 5, 2016

Abstract

We propose a low-power variable optical attenuator based on the configuration of a hybrid silicon oxynitride (SiON)-polymer S-bend waveguide and two grooves in both sides of the S-bend waveguide core. With such a configuration, the opposite thermo-optic characteristics of SiON and polymer materials can be fully utilized. As a consequence, the heat utilization efficiency is increased. Theoretical simulation shows that an optical attenuation of $\sim 50 dB$ can be achieved with an applied electrical power of 3.6 mW. A typical fabricated device, which has a total length of 8 mm, shows a maximum optical attenuation of 46 dB with an applied electrical power of 16.2 mW and an insertion loss of 5.4 dB.

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Configurations	Insertion loss	Maximum optical attenuation	Driving Power/Temperature/Voltage	Ref.
MEMS	N/A	19.24 dB	68°C	[4]
Microfluidic	N/A	35 dB	N/A	[5]
Microfluidic	N/A	26 dB	N/A	[6]
LC	N/A	29.2 dB	37.5 V	[7]
LC	8 dB	20 dB	80 V	[8]
PLC-MZI	N/A	25 dB	50 mW	[11]
PLC-MZI	$\sim 8.1$	29.3 dB	1.96 mW	[12]
PLC-MZI	N/A	35 dB	10.1 mW	[13]
PLC-MMI	N/A	50 dB	1.8 mW	[13]
Straight waveguide	N/A	27 dB	7	[17]
Bent waveguide	1.57 dB	$> 40 dB$	250 mW	[18]
Y-junction	$\sim 5 dB$	20 dB	$\sim 200 mW$	[20]
Straight waveguide	17 dB	41.4 dB	10 V	[21]

Materials	Thermal Conductivity (W/m·K)
Cr	93.7
BCB and Epoclad	0.22
SiON	1.4
${SiO}_{2}$	2.0

Configurations	Insertion loss	Maximum optical attenuation	Driving Power/Temperature/Voltage	Ref.
MEMS	N/A	19.24 dB	68°C	[4]
Microfluidic	N/A	35 dB	N/A	[5]
Microfluidic	N/A	26 dB	N/A	[6]
LC	N/A	29.2 dB	37.5 V	[7]
LC	8 dB	20 dB	80 V	[8]
PLC-MZI	N/A	25 dB	50 mW	[11]
PLC-MZI	$\sim 8.1$	29.3 dB	1.96 mW	[12]
PLC-MZI	N/A	35 dB	10.1 mW	[13]
PLC-MMI	N/A	50 dB	1.8 mW	[13]
Straight waveguide	N/A	27 dB	7	[17]
Bent waveguide	1.57 dB	$> 40 dB$	250 mW	[18]
Y-junction	$\sim 5 dB$	20 dB	$\sim 200 mW$	[20]
Straight waveguide	17 dB	41.4 dB	10 V	[21]

Materials	Thermal Conductivity (W/m·K)
Cr	93.7
BCB and Epoclad	0.22
SiON	1.4
${SiO}_{2}$	2.0

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Applied Optics