# Excitonic lasing of strain-free InP(As) quantum dots in AlInAs microdisk

**Authors:** D. V. Lebedev (1), M. M. Kulagina (1), S. I. Troshkov (1), A. A., Bogdanov (2), A. S. Vlasov (1), V. Yu. Davydov (1), A. N. Smirnov (1), J. L., Merz (2), J. Kapaldo (3), A. Gocalinska (4), G. Juska (4), S. T. Moroni (4),, E. Pelucchi (4), D. Barettin (5), S. Rouvimov (1, 2), A. M. Mintairov, (1, 2) ((1) Ioffe Physico-Technical Institute, (2) ITMO University, (3), Electrical Engineering University of Notre Dame, (4) Physics Department,, University of Notre Dame, (4) Tyndall National Institute, University College, Cork, (5) Universit\`a Niccolo Cusano, University of Rome, Tor Vergata)

arXiv: 1704.01635 · 2017-04-07

## TL;DR

This study demonstrates excitonic lasing in strain-free InP(As) quantum dots embedded in AlInAs microdisks, revealing their optical properties, lasing behavior, and potential for integrated photonics.

## Contribution

It reports the first observation of excitonic lasing in strain-free InP(As) quantum dots within microdisk cavities, including detailed characterization and lasing parameters.

## Key findings

- Quantum dots emit at ~940 nm with strong temperature quenching.
- Lasing occurs in whispering gallery modes with Q up to 13000.
- Threshold for lasing is approximately 50 W/cm².

## Abstract

Formation, emission and lasing properties of strain-free InP(As)/AlInAs quantum dots (QDs) embedded in AlInAs microdisk (MD) cavity were investigated using transmission electron microscopy and photoluminescence (PL) techniques. In MD structures, the QDs having nano-pan-cake shape have height of ~2 nm, lateral size of 20-50 nm and density of ~5x109 cm-2. Their emission observed at ~940 nm revealed strong temperature quenching, which points to exciton decomposition. It also showed unexpected type-I character indicating In-As intermixing, as confirmed by band structure calculations. We observed lasing of InP(As) QD excitons into whispering gallery modes in MD having dimeter ~3.2 mkm and providing free spectral range of ~27 nm and quality factors up to Q~13000. Threshold of ~50 W/cm2 and spontaneous emission coupling coefficient of ~0.2 were measured for this MD-QD system.

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Source: https://tomesphere.com/paper/1704.01635