Mechanically induced optical loss mechanism due to thermal expansion coefficient mismatch in micro-cavities with all-around stressor layers
Mechanically induced optical loss mechanism due to thermal expansion coefficient mismatch in micro-cavities with all-around stressor layers
Various excitation-induced loss mechanisms have been identified during the development of direct-gap semiconductor lasers. Recently, indirect-gap laser sources, particularly germanium (Ge) or GeSn based, have emerged due to silicon industry compatibility. Tensile strain is crucial for optical gain or low-threshold room-temperature operation in such media. This study investigates an excitation-induced optical loss mechanism of mechanical origin in Ge-based micro-cavities with all-around stressor layers, a popular platform for strain-engineered laser sources. Using Raman spectroscopy, photoluminescence, and simulations, we find that excitation lowers the optical gain by altering the strain profile. Heating causes Ge micro-cavities to expand within a constraining stressor layer, inducing compressive strain, which is explained by the mismatch in thermal expansion coefficients.
Al-Attili, Abdelrahman Z.
534a1c1f-3f8c-4a78-b71b-50c156e23373
Burt, Daniel
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Rahman, Tasmiat
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Li, Zuo
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Higashitarumizu, Naoki
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Gardes, Frederic Y.
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Ishikawa, Yashuhiko
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Saito, Shinichi
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Al-Attili, Abdelrahman Z.
534a1c1f-3f8c-4a78-b71b-50c156e23373
Burt, Daniel
49c801a2-fb48-40f2-b72f-f713151b96e6
Rahman, Tasmiat
e7432efa-2683-484d-9ec6-2f9c568d30cd
Li, Zuo
d9abc57a-6283-4819-b7bd-9c1b64e66a0c
Higashitarumizu, Naoki
0a322ee5-f9f7-45d0-82d3-c3194caa4f52
Gardes, Frederic Y.
7a49fc6d-dade-4099-b016-c60737cb5bb2
Ishikawa, Yashuhiko
36692c79-257f-4224-811a-c43227922ed3
Saito, Shinichi
14a5d20b-055e-4f48-9dda-267e88bd3fdc
Al-Attili, Abdelrahman Z., Burt, Daniel, Rahman, Tasmiat, Li, Zuo, Higashitarumizu, Naoki, Gardes, Frederic Y., Ishikawa, Yashuhiko and Saito, Shinichi
(2024)
Mechanically induced optical loss mechanism due to thermal expansion coefficient mismatch in micro-cavities with all-around stressor layers.
APL Photonics, 9 (5), [056104].
(doi:10.1063/5.0203305).
Abstract
Various excitation-induced loss mechanisms have been identified during the development of direct-gap semiconductor lasers. Recently, indirect-gap laser sources, particularly germanium (Ge) or GeSn based, have emerged due to silicon industry compatibility. Tensile strain is crucial for optical gain or low-threshold room-temperature operation in such media. This study investigates an excitation-induced optical loss mechanism of mechanical origin in Ge-based micro-cavities with all-around stressor layers, a popular platform for strain-engineered laser sources. Using Raman spectroscopy, photoluminescence, and simulations, we find that excitation lowers the optical gain by altering the strain profile. Heating causes Ge micro-cavities to expand within a constraining stressor layer, inducing compressive strain, which is explained by the mismatch in thermal expansion coefficients.
Text
056104_1_5.0203305
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Accepted/In Press date: 25 April 2024
e-pub ahead of print date: 10 May 2024
Identifiers
Local EPrints ID: 492527
URI: http://eprints.soton.ac.uk/id/eprint/492527
ISSN: 2378-0967
PURE UUID: 05372127-93ec-4b42-bd7b-458f46db2c15
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Date deposited: 30 Jul 2024 17:00
Last modified: 31 Jul 2024 01:48
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Contributors
Author:
Abdelrahman Z. Al-Attili
Author:
Daniel Burt
Author:
Tasmiat Rahman
Author:
Zuo Li
Author:
Naoki Higashitarumizu
Author:
Frederic Y. Gardes
Author:
Yashuhiko Ishikawa
Author:
Shinichi Saito
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