Threshold behavior in quantum-dot nanolasers: effects of inhomogeneous broadening
Threshold behavior in quantum-dot nanolasers: effects of inhomogeneous broadening
We investigate the threshold behavior of lasers under various modeling approaches, considering different numbers of non-lasing cavity modes and analyzing the effects of radiation–matter coupling strength, cavity lifetime, and quantum dot properties. Thermal and electron–electron decoherence are incorporated as phenomenological relaxation processes, in line with established practices. Both spectrally uniform and polydisperse quantum dots are examined. For the former, we observe strong agreement across modeling approaches: the qualitative behavior remains consistent, with threshold pump values showing quantitative shifts depending on the specific model. In the case of polydisperse quantum dots, leading to inhomogeneous broadening, this picture is reaffirmed –- each model type exhibits similar qualitative trends, while threshold variations arise due to the stochastic distribution of emitter transition frequencies. Our results confirm that models that assume homogeneous quantum dots are suitable for comparison with experimental data and that inhomogeneous effects can be directly captured using our framework when required.
Quantum dots, nanolaser, Quantum optics, light-matter interaction
D'Alessandro, Giampaolo
bad097e1-9506-4b6e-aa56-3e67a526e83b
Lippi, Gian Luca
ec4e6c7e-f969-4774-8e20-cb02b1504f21
Papoff, Francesco
c845380e-f3e9-4c20-9d6c-0b7a66918174
11 December 2025
D'Alessandro, Giampaolo
bad097e1-9506-4b6e-aa56-3e67a526e83b
Lippi, Gian Luca
ec4e6c7e-f969-4774-8e20-cb02b1504f21
Papoff, Francesco
c845380e-f3e9-4c20-9d6c-0b7a66918174
D'Alessandro, Giampaolo, Lippi, Gian Luca and Papoff, Francesco
(2025)
Threshold behavior in quantum-dot nanolasers: effects of inhomogeneous broadening.
Physical Review A, 112 (6), [063521].
(doi:10.1103/m9px-p28x).
Abstract
We investigate the threshold behavior of lasers under various modeling approaches, considering different numbers of non-lasing cavity modes and analyzing the effects of radiation–matter coupling strength, cavity lifetime, and quantum dot properties. Thermal and electron–electron decoherence are incorporated as phenomenological relaxation processes, in line with established practices. Both spectrally uniform and polydisperse quantum dots are examined. For the former, we observe strong agreement across modeling approaches: the qualitative behavior remains consistent, with threshold pump values showing quantitative shifts depending on the specific model. In the case of polydisperse quantum dots, leading to inhomogeneous broadening, this picture is reaffirmed –- each model type exhibits similar qualitative trends, while threshold variations arise due to the stochastic distribution of emitter transition frequencies. Our results confirm that models that assume homogeneous quantum dots are suitable for comparison with experimental data and that inhomogeneous effects can be directly captured using our framework when required.
Text
m9px-p28x
- Version of Record
More information
Accepted/In Press date: 10 November 2025
Published date: 11 December 2025
Keywords:
Quantum dots, nanolaser, Quantum optics, light-matter interaction
Identifiers
Local EPrints ID: 508112
URI: http://eprints.soton.ac.uk/id/eprint/508112
ISSN: 1050-2947
PURE UUID: a8b3d511-3e45-41e7-8e94-c6d73789ca40
Catalogue record
Date deposited: 13 Jan 2026 17:54
Last modified: 14 Jan 2026 02:34
Export record
Altmetrics
Contributors
Author:
Gian Luca Lippi
Author:
Francesco Papoff
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
