Effect of p-doping on the intensity noise of epitaxial quantum dot lasers on silicon

Jianan Duan; Yueguang Zhou; Yueguang Zhou; Bozhang Dong; Heming Huang; Justin C. Norman; Justin C. Norman; Daehwan Jung; Daehwan Jung; Zeyu Zhang; Cheng Wang; John E. Bowers; John E. Bowers; John E. Bowers; Frédéric Grillot; Frédéric Grillot

doi:10.1364/OL.395499

Optics Letters
Vol. 45,
Issue 17,
pp. 4887-4890
(2020)
•https://doi.org/10.1364/OL.395499

Effect of p-doping on the intensity noise of epitaxial quantum dot lasers on silicon

Jianan Duan, Yueguang Zhou, Bozhang Dong, Heming Huang, Justin C. Norman, Daehwan Jung, Zeyu Zhang, Cheng Wang, John E. Bowers, and Frédéric Grillot

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Jianan Duan, Yueguang Zhou, Bozhang Dong, Heming Huang, Justin C. Norman, Daehwan Jung, Zeyu Zhang, Cheng Wang, John E. Bowers, and Frédéric Grillot, "Effect of p-doping on the intensity noise of epitaxial quantum dot lasers on silicon," Opt. Lett. 45, 4887-4890 (2020)

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- Lasers and Laser Optics
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About this Article
History
- Original Manuscript: April 17, 2020
- Revised Manuscript: July 22, 2020
- Manuscript Accepted: August 3, 2020
- Published: August 31, 2020

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Abstract

This work experimentally investigates the impact of p-doping on the relative intensity noise (RIN) properties and subsequently on the modulation properties of semiconductor quantum dot (QD) lasers epitaxially grown on silicon. Owing to the low threading dislocation density and the p-modulation doped GaAs barrier layer in the active region, the RIN level is found very stable with temperature with a minimum value of ${-}{{150}}\;{\rm{dB/Hz}}$. The dynamical features extracted from the RIN spectra show that p-doping between zero and 20 holes/dot strongly modifies the modulation properties and gain nonlinearities through increased internal losses in the active region and thereby hinders the maximum achievable bandwidth. Overall, this Letter is important for designing future high-speed and low-noise QD devices integrated in future photonic integrated circuits.

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Device	A	B	C
Doping ( ${c m}^{- 3}$ )	0	$0.5 \times 10^{18}$	$1.0 \times 10^{18}$
Holes per QD	0	10	20
$I_{t h}$ (mA)	13	23	39
$J_{t h} (A / {c m}^{2})$	296	426	722
K(ns)	4.7	1.7	1.5
$γ_{0}$ (GHz)	1.5	3.0	5.2
$τ_{c} (n s)$	0.7	0.3	0.2
$f_{3 d B, max}$ (GHz)	1.9	5.2	5.9
$ϵ_{p} (m W^{- 1})$	0.15	0.27	0.40
$ϵ_{S} ({c m}^{3})$	$5.7 \times 10^{- 16}$	$1.0 \times 10^{- 15}$	$1.5 \times 10^{- 15}$

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Optics Letters