We report the unequivocal demonstration of mid-infrared mode-locked pulses
from a semiconductor laser. The train of short pulses was generated by actively
modulating the current and hence the optical gain in a small section of an
edge-emitting quantum cascade laser (QCL). Pulses with pulse duration at
full-width-at-half-maximum of about 3 ps and energy of 0.5 pJ were
characterized using a second-order interferometric autocorrelation technique
based on a nonlinear quantum well infrared photodetector. The mode-locking
dynamics in the QCLs was modelled and simulated based on Maxwell-Bloch
equations in an open two-level system. We anticipate our results to be a
significant step toward a compact, electrically-pumped source generating
ultrashort light pulses in the mid-infrared and terahertz spectral ranges.Comment: 26 pages, 4 figure

A. Belyanin

Barbieri

C. Y. Song

Capasso

Choi

Christine Y. Wang

D. Ham

de Barros

Dudley

F. X. Kärtner

Faist

Federico Capasso

French

Gibson

Gmachl

Gordon

Grant

H. Schneider

H.C. Liu

Haus

Huber

Jianmeng Li

L. Diehl

Loza-Alvarez

Lyuba Kuznetsova

M. A. Belkin

Macklin

Maier

Meshulach

Okamoto

P. Grant

Paiella

S. Haffouz

Torre

Udem

V. M. Gkortsas

Wang

Warren

X. Li

Z. R. Wasilewski

Optics Express

English

arXiv

In this study, we report the unequivocal demonstration of midinfrared mode-locked pulses from quantum cascade lasers. The train of short pulses was generated by actively modulating the current and hence the gain of an edge-emitting quantum cascade laser (QCL). Pulses with duration of about 3 ps at full-width-at-half-maxima and energy of 0.5 pJ were characterized using a second-order interferometric autocorrelation technique based on a nonlinear quantum well infrared photodetector. The modelocking dynamics in the QCLs was modeled based on the Maxwell-Bloch equations in an open two-level system. Our model reproduces the overall shape of the measured autocorrelation traces and predicts that the short pulses are accompanied by substantial wings as a result of strong spatial hole burning. The range of parameters where short mode-locked pulses can be formed is found.Peer reviewed: NoNRC publication: Ye

Wang, Christine Y.

Kyznetsova, Lyuba

Gkortsas, V.M.

Diehl, L.

Kartner, F.X.

Belkin, M.A.

Belyanin, A.

Li, X.

Ham, D.

Schneider, H.

Grant, P.

Song, C.Y.

Haffouz, S.

Wasilewski, Z.R.

Liu, H.C.

Capasso, Federico

NRC Publications Archive

Mode-locked pulses from mid-infrared Quantum Cascade Lasers

Crossref

In this study, we report the unequivocal demonstration of midinfrared mode-locked pulses from quantum cascade lasers. The train of short pulses was generated by actively modulating the current and hence the gain of an edge-emitting quantum cascade laser (QCL). Pulses with duration of about 3 ps at full-width-at-half-maxima and energy of 0.5 pJ were characterized using a second-order interferometric autocorrelation technique based on a nonlinear quantum well infrared photodetector. The mode-locking dynamics in the QCLs was modeled based on the Maxwell-Bloch equations in an open two-level system. Our model reproduces the overall shape of the measured autocorrelation traces and predicts that the short pulses are accompanied by substantial wings as a result of strong spatial hole burning. The range of parameters where short mode-locked pulses can be formed is found.Engineering and Applied SciencesVersion of Recor

Kuznetsova, Lyuba

Gkotsas, Vasileios‐Marios

Diehl, L

Kaertner, Franz X.

Belkin, Mikhail A.

Belyanin, Alexey

Li, Xiaofeng

Ham, Donhee

Schneider, Harald

Grant, Peter

Song, C. Y.

Haffouz, Soufien

Wasilewski, Zbigniew

Liu, H. C.

Harvard University - DASH

Mode-Locked Pulses from Mid-Infrared Quantum Cascade Lasers

Gkortsas, V. M.

K��rtner, F. X.

Belkin, M. A.

Wasilewski, Z. R.

OAKTrust Digital Repository (Texas A&M Univ)

https://dash.harvard.edu/bitstream/handle/1/3425949/Wang_OE_17_12929_2009.pdf?sequence=2