The University of Southampton
×
Filter your search:
University of Southampton Institutional Repository

Wafer-scale demonstration of low-loss (∼0.43 dB/cm), high-bandwidth (>38 GHz), silicon photonics platform operating at the C-band

Wafer-scale demonstration of low-loss (∼0.43 dB/cm), high-bandwidth (>38 GHz), silicon photonics platform operating at the C-band
Wafer-scale demonstration of low-loss (∼0.43 dB/cm), high-bandwidth (>38 GHz), silicon photonics platform operating at the C-band

The key advantage of silicon photonics comes from its potential for large scale integration, in a low-cost and scalable fashion. This has sustained the growth in the area despite disadvantages such as the lack of a monolithic light source, or the absence of a second order non-linear response (χ(2)). Thus far, the work in the field has focused on reporting individual devices from a single die, with excellent performances. Wafer-level results, an area which has not been addressed sufficiently, is a critical aspect of silicon photonics and will provide the community with information regarding scalability and variation, which will be the key differentiating advantage of silicon photonics over other photonic platforms. In this work, we report the development of a low-loss, high-bandwidth C-band silicon photonic platform on a 200 mm CMOS-compatible process line, demonstrating wafer-level performance in the process. Ultra-low waveguide propagation loss with median values as low as 0.43 dB/cm has been achieved. Silicon Mach-Zehnder and microring modulators with median bandwidth of 38.5 and 43 GHz respectively are presented. Finally, germanium waveguide-integrated photodetectors with median bandwidth of 43 GHz are reported. The results reported in this work are comparable to prior demonstrations concerning individual devices. The baseline designs on this platform presented in this work can be accessed commercially from CompoundTek.

Modulator, photodetector, photonic integrated circuits, silicon photonics, wafer-level platform, waveguide
1943-0655
Sia, Jia Xu Brian
996b6cec-fd29-4301-9eae-b8b21dbe1405
Li, Xiang
358bd9e7-59c3-45fe-93e9-8855ee227f31
Wang, Jiawei
9785f518-63ea-405d-be85-c8f2800f2098
Wang, Wanjun
79108a43-c2a9-4a18-9aeb-8a9b45941dd0
Qiao, Zhongliang
c70103ef-3b61-456d-95ff-b760d74bea4f
Guo, Xin
c1da16ff-f2d9-4500-92c7-aafb401efab8
Lee, Chee Wei
ec09851f-9ffa-4e93-8e80-4cf58a31d9a0
Sasidharan, Ashesh
a9b2c555-2f70-4bf5-887a-4daaf926f06a
Gunasagar, S.
105b25f7-81bb-4352-9510-c70111a4729e
Littlejohns, Callum G.
d2837f04-0a83-4bf9-acb2-618aa42a0cad
Liu, Chongyang
46565e0b-5d4d-407e-8d3a-ee2d344fe21a
Reed, Graham T.
ca08dd60-c072-4d7d-b254-75714d570139
Ang, Kian Siong
2b0cfc8a-904e-4729-92ca-c11cc9d3ff08
Wang, Hong
dfd0ec4f-682a-4596-a0d1-171313cc5733
Sia, Jia Xu Brian
996b6cec-fd29-4301-9eae-b8b21dbe1405
Li, Xiang
358bd9e7-59c3-45fe-93e9-8855ee227f31
Wang, Jiawei
9785f518-63ea-405d-be85-c8f2800f2098
Wang, Wanjun
79108a43-c2a9-4a18-9aeb-8a9b45941dd0
Qiao, Zhongliang
c70103ef-3b61-456d-95ff-b760d74bea4f
Guo, Xin
c1da16ff-f2d9-4500-92c7-aafb401efab8
Lee, Chee Wei
ec09851f-9ffa-4e93-8e80-4cf58a31d9a0
Sasidharan, Ashesh
a9b2c555-2f70-4bf5-887a-4daaf926f06a
Gunasagar, S.
105b25f7-81bb-4352-9510-c70111a4729e
Littlejohns, Callum G.
d2837f04-0a83-4bf9-acb2-618aa42a0cad
Liu, Chongyang
46565e0b-5d4d-407e-8d3a-ee2d344fe21a
Reed, Graham T.
ca08dd60-c072-4d7d-b254-75714d570139
Ang, Kian Siong
2b0cfc8a-904e-4729-92ca-c11cc9d3ff08
Wang, Hong
dfd0ec4f-682a-4596-a0d1-171313cc5733

Sia, Jia Xu Brian, Li, Xiang, Wang, Jiawei, Wang, Wanjun, Qiao, Zhongliang, Guo, Xin, Lee, Chee Wei, Sasidharan, Ashesh, Gunasagar, S., Littlejohns, Callum G., Liu, Chongyang, Reed, Graham T., Ang, Kian Siong and Wang, Hong (2022) Wafer-scale demonstration of low-loss (∼0.43 dB/cm), high-bandwidth (>38 GHz), silicon photonics platform operating at the C-band. IEEE Photonics Journal, 14 (3), [6628609]. (doi:10.1109/JPHOT.2022.3170366).

Record type: Article

Abstract

The key advantage of silicon photonics comes from its potential for large scale integration, in a low-cost and scalable fashion. This has sustained the growth in the area despite disadvantages such as the lack of a monolithic light source, or the absence of a second order non-linear response (χ(2)). Thus far, the work in the field has focused on reporting individual devices from a single die, with excellent performances. Wafer-level results, an area which has not been addressed sufficiently, is a critical aspect of silicon photonics and will provide the community with information regarding scalability and variation, which will be the key differentiating advantage of silicon photonics over other photonic platforms. In this work, we report the development of a low-loss, high-bandwidth C-band silicon photonic platform on a 200 mm CMOS-compatible process line, demonstrating wafer-level performance in the process. Ultra-low waveguide propagation loss with median values as low as 0.43 dB/cm has been achieved. Silicon Mach-Zehnder and microring modulators with median bandwidth of 38.5 and 43 GHz respectively are presented. Finally, germanium waveguide-integrated photodetectors with median bandwidth of 43 GHz are reported. The results reported in this work are comparable to prior demonstrations concerning individual devices. The baseline designs on this platform presented in this work can be accessed commercially from CompoundTek.

Text
Wafer-Scale_Demonstration_of_Low-Loss_0.43_dB_cm_High-Bandwidth_gt38_GHz_Silicon_Photonics_Platform_Operating_at_the_C-Band - Version of Record
Available under License Creative Commons Attribution.
Download (4MB)

More information

e-pub ahead of print date: 26 June 2022
Keywords: Modulator, photodetector, photonic integrated circuits, silicon photonics, wafer-level platform, waveguide
Learn more about Zepler Institute for Photonics and Nanoelectronics research

Identifiers

Local EPrints ID: 481524
URI: http://eprints.soton.ac.uk/id/eprint/481524
DOI: doi:10.1109/JPHOT.2022.3170366
ISSN: 1943-0655
PURE UUID: 9daba09f-7926-4bf1-bf2d-e42faf6eda3f

Catalogue record

Date deposited: 31 Aug 2023 16:41
Last modified: 17 Mar 2024 04:21

Export record

Altmetrics

Contributors

Author: Jia Xu Brian Sia
Author: Xiang Li
Author: Jiawei Wang
Author: Wanjun Wang
Author: Zhongliang Qiao
Author: Xin Guo
Author: Chee Wei Lee
Author: Ashesh Sasidharan
Author: S. Gunasagar
Author: Callum G. Littlejohns
Author: Chongyang Liu
Author: Graham T. Reed
Author: Kian Siong Ang
Author: Hong Wang

Download statistics

Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.

View more statistics

Library staff additional information
Atom RSS 1.0 RSS 2.0

Contact ePrints Soton: eprints@soton.ac.uk

ePrints Soton supports OAI 2.0 with a base URL of http://eprints.soton.ac.uk/cgi/oai2

This repository has been built using EPrints software, developed at the University of Southampton, but available to everyone to use.

We use cookies to ensure that we give you the best experience on our website. If you continue without changing your settings, we will assume that you are happy to receive cookies on the University of Southampton website.

×