Perspectives on Advances in Quantum Dot Lasers and Integration with Si Photonic Integrated Circuits

Chen Shang; Yating Wan; Jennifer Selvidge; Eamonn Hughes; Robert Herrick; Kunal Mukherjee; Jianan Duan; Frederic Grillot; Weng W. Chow; John E. Bowers

doi:10.1021/acsphotonics.1c00707

Perspectives on Advances in Quantum Dot Lasers and Integration with Si Photonic Integrated Circuits

Chen Shang
, Yating Wan
, Jennifer Selvidge
, Eamonn Hughes
, Robert Herrick
, Kunal Mukherjee
, Jianan Duan
, Frederic Grillot
, Weng W. Chow
, John E. Bowers

Research output: Contribution to journal › Review article › peer-review

Abstract

Epitaxially grown quantum dot (QD) lasers are emerging as an economical approach to obtain on-chip light sources. Thanks to the three-dimensional confinement of carriers, QDs show greatly improved tolerance to defects and promise other advantages such as low transparency current density, high temperature operation, isolator-free operation, and enhanced four-wave-mixing. These material properties distinguish them from traditional III-V/Si quantum wells (QWs) and have spawned intense interest to explore a full set of photonic integration using epitaxial growth technology. We present here a summary of the most recent developments of QD lasers grown on a CMOS-compatible (001) Si substrate, with a focus on breakthroughs in long lifetime at elevated temperatures. Threading dislocations are significantly reduced to the level of 1 × 10⁶cm^-2via a novel asymmetric step-graded filter. Misfit dislocations are efficiently blocked from the QD region through well-engineered trapping layers. A record-breaking extrapolated lifetime of more than 200000 hours has been achieved at 80 °C, forecasting that device reliability is now entering the realm of commercial relevance and a monolithically integrated light source is finally on the horizon.

Original language	English
Pages (from-to)	2555-2566
Number of pages	12
Journal	ACS Photonics
Volume	8
Issue number	9
DOIs	https://doi.org/10.1021/acsphotonics.1c00707
Publication status	Published - 15 Sept 2021

Keywords

Si photonics
heteroepitaxial growth
lifetime
monolithic integration
on-chip lasers
quantum dot (QD)

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10.1021/acsphotonics.1c00707

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title = "Perspectives on Advances in Quantum Dot Lasers and Integration with Si Photonic Integrated Circuits",

abstract = "Epitaxially grown quantum dot (QD) lasers are emerging as an economical approach to obtain on-chip light sources. Thanks to the three-dimensional confinement of carriers, QDs show greatly improved tolerance to defects and promise other advantages such as low transparency current density, high temperature operation, isolator-free operation, and enhanced four-wave-mixing. These material properties distinguish them from traditional III-V/Si quantum wells (QWs) and have spawned intense interest to explore a full set of photonic integration using epitaxial growth technology. We present here a summary of the most recent developments of QD lasers grown on a CMOS-compatible (001) Si substrate, with a focus on breakthroughs in long lifetime at elevated temperatures. Threading dislocations are significantly reduced to the level of 1 × 106cm-2via a novel asymmetric step-graded filter. Misfit dislocations are efficiently blocked from the QD region through well-engineered trapping layers. A record-breaking extrapolated lifetime of more than 200000 hours has been achieved at 80 °C, forecasting that device reliability is now entering the realm of commercial relevance and a monolithically integrated light source is finally on the horizon.",

keywords = "Si photonics, heteroepitaxial growth, lifetime, monolithic integration, on-chip lasers, quantum dot (QD)",

author = "Chen Shang and Yating Wan and Jennifer Selvidge and Eamonn Hughes and Robert Herrick and Kunal Mukherjee and Jianan Duan and Frederic Grillot and Chow, \{Weng W.\} and Bowers, \{John E.\}",

note = "Publisher Copyright: {\textcopyright} 2021 The Authors. Published by American Chemical Society",

year = "2021",

month = sep,

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doi = "10.1021/acsphotonics.1c00707",

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T1 - Perspectives on Advances in Quantum Dot Lasers and Integration with Si Photonic Integrated Circuits

AU - Shang, Chen

AU - Wan, Yating

AU - Selvidge, Jennifer

AU - Hughes, Eamonn

AU - Herrick, Robert

AU - Mukherjee, Kunal

AU - Duan, Jianan

AU - Grillot, Frederic

AU - Chow, Weng W.

AU - Bowers, John E.

PY - 2021/9/15

Y1 - 2021/9/15

N2 - Epitaxially grown quantum dot (QD) lasers are emerging as an economical approach to obtain on-chip light sources. Thanks to the three-dimensional confinement of carriers, QDs show greatly improved tolerance to defects and promise other advantages such as low transparency current density, high temperature operation, isolator-free operation, and enhanced four-wave-mixing. These material properties distinguish them from traditional III-V/Si quantum wells (QWs) and have spawned intense interest to explore a full set of photonic integration using epitaxial growth technology. We present here a summary of the most recent developments of QD lasers grown on a CMOS-compatible (001) Si substrate, with a focus on breakthroughs in long lifetime at elevated temperatures. Threading dislocations are significantly reduced to the level of 1 × 106cm-2via a novel asymmetric step-graded filter. Misfit dislocations are efficiently blocked from the QD region through well-engineered trapping layers. A record-breaking extrapolated lifetime of more than 200000 hours has been achieved at 80 °C, forecasting that device reliability is now entering the realm of commercial relevance and a monolithically integrated light source is finally on the horizon.

AB - Epitaxially grown quantum dot (QD) lasers are emerging as an economical approach to obtain on-chip light sources. Thanks to the three-dimensional confinement of carriers, QDs show greatly improved tolerance to defects and promise other advantages such as low transparency current density, high temperature operation, isolator-free operation, and enhanced four-wave-mixing. These material properties distinguish them from traditional III-V/Si quantum wells (QWs) and have spawned intense interest to explore a full set of photonic integration using epitaxial growth technology. We present here a summary of the most recent developments of QD lasers grown on a CMOS-compatible (001) Si substrate, with a focus on breakthroughs in long lifetime at elevated temperatures. Threading dislocations are significantly reduced to the level of 1 × 106cm-2via a novel asymmetric step-graded filter. Misfit dislocations are efficiently blocked from the QD region through well-engineered trapping layers. A record-breaking extrapolated lifetime of more than 200000 hours has been achieved at 80 °C, forecasting that device reliability is now entering the realm of commercial relevance and a monolithically integrated light source is finally on the horizon.

KW - Si photonics

KW - heteroepitaxial growth

KW - lifetime

KW - monolithic integration

KW - on-chip lasers

KW - quantum dot (QD)

UR - https://www.scopus.com/pages/publications/85113962703

U2 - 10.1021/acsphotonics.1c00707

DO - 10.1021/acsphotonics.1c00707

M3 - Review article

AN - SCOPUS:85113962703

SN - 2330-4022

VL - 8

SP - 2555

EP - 2566

JO - ACS Photonics

JF - ACS Photonics

IS - 9

ER -

Perspectives on Advances in Quantum Dot Lasers and Integration with Si Photonic Integrated Circuits

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