Evaluating the Local Bandgap Across inxGa1-xas Multiple Quantum Wells in a Metamorphic Laser via Low-Loss EELS

Nicholas Stephen; Ivan Pinto-Huguet; Robert Lawrence; Demie Kepaptsoglou; Marc Botifoll; Agnieszka Gocalinska; Enrica Mura; Quentin Ramasse; Emanuele Pelucchi; Jordi Arbiol; Miryam Arredondo

doi:10.1002/admi.202400897

Evaluating the Local Bandgap Across inxGa1-xas Multiple Quantum Wells in a Metamorphic Laser via Low-Loss EELS

Nicholas Stephen, Ivan Pinto-Huguet, Robert Lawrence, Demie Kepaptsoglou, Marc Botifoll, Agnieszka Gocalinska, Enrica Mura, Quentin Ramasse, Emanuele Pelucchi, Jordi Arbiol, Miryam Arredondo

Physics

Research output: Contribution to journal › Article › peer-review

Abstract

Abstract Using high-resolution scanning transmission electron microscopy and low-loss electron energy loss spectroscopy, the local bandgap (Eg), indium concentration, and strain distribution across multiple InxGa1-xAs quantum wells (QWs), on a GaAs substrate, within a metamorphic laser structure are correlated. The findings reveal significant inhomogeneities, particularly near the interfaces, for both the indium and strain distribution, and subtle variations in the Eg across individual QWs. The interplay between strain, composition, and Eg is further explored by density functional theory simulations, indicating that variations in the Eg are predominantly influenced by the indium concentration, with strain playing a minor role. The observed local inhomogeneities suggest that differences between individual QWs may affect the collective emission and performance of the final device. This study highlights the importance of spatially resolved analysis in understanding and optimizing the electronic and optical properties for designing next-generation metamorphic lasers with multiple QWs as the active region.

Original language	English
Article number	2400897
Number of pages	8
Journal	Advanced materials interfaces
Volume	n/a
Issue number	n/a
Early online date	4 Apr 2025
DOIs	https://doi.org/10.1002/admi.202400897
Publication status	E-pub ahead of print - 4 Apr 2025

Keywords

bandgap
electron energy loss spectroscopy
in concentration
InGaAs
quantum well
strain distribution

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10.1002/admi.202400897Licence: CC BY

Adv Materials Inter - 2025 - Stephen - Evaluating the Local Bandgap Across inxGa1‐xas Multiple Quantum Wells in a
© 2025 The Author(s).
Final published version, 4.89 MBLicence: CC BY

1 Active

SuperSTEM: National Research Facility for Advanced Electron Microscopy
Kepaptsoglou, D. (Co-investigator)
14/03/22 → 13/03/27
Project: Research project (funded) › Research

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Stephen, N., Pinto-Huguet, I., Lawrence, R., Kepaptsoglou, D., Botifoll, M., Gocalinska, A., Mura, E., Ramasse, Q., Pelucchi, E., Arbiol, J., & Arredondo, M. (2025). Evaluating the Local Bandgap Across inxGa1-xas Multiple Quantum Wells in a Metamorphic Laser via Low-Loss EELS. Advanced materials interfaces, n/a(n/a), Article 2400897. Advance online publication. https://doi.org/10.1002/admi.202400897

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title = "Evaluating the Local Bandgap Across inxGa1-xas Multiple Quantum Wells in a Metamorphic Laser via Low-Loss EELS",

abstract = "Abstract Using high-resolution scanning transmission electron microscopy and low-loss electron energy loss spectroscopy, the local bandgap (Eg), indium concentration, and strain distribution across multiple InxGa1-xAs quantum wells (QWs), on a GaAs substrate, within a metamorphic laser structure are correlated. The findings reveal significant inhomogeneities, particularly near the interfaces, for both the indium and strain distribution, and subtle variations in the Eg across individual QWs. The interplay between strain, composition, and Eg is further explored by density functional theory simulations, indicating that variations in the Eg are predominantly influenced by the indium concentration, with strain playing a minor role. The observed local inhomogeneities suggest that differences between individual QWs may affect the collective emission and performance of the final device. This study highlights the importance of spatially resolved analysis in understanding and optimizing the electronic and optical properties for designing next-generation metamorphic lasers with multiple QWs as the active region.",

keywords = "bandgap, electron energy loss spectroscopy, in concentration, InGaAs, quantum well, strain distribution",

author = "Nicholas Stephen and Ivan Pinto-Huguet and Robert Lawrence and Demie Kepaptsoglou and Marc Botifoll and Agnieszka Gocalinska and Enrica Mura and Quentin Ramasse and Emanuele Pelucchi and Jordi Arbiol and Miryam Arredondo",

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AU - Stephen, Nicholas

AU - Pinto-Huguet, Ivan

AU - Lawrence, Robert

AU - Kepaptsoglou, Demie

AU - Botifoll, Marc

AU - Gocalinska, Agnieszka

AU - Mura, Enrica

AU - Ramasse, Quentin

AU - Pelucchi, Emanuele

AU - Arbiol, Jordi

AU - Arredondo, Miryam

PY - 2025/4/4

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N2 - Abstract Using high-resolution scanning transmission electron microscopy and low-loss electron energy loss spectroscopy, the local bandgap (Eg), indium concentration, and strain distribution across multiple InxGa1-xAs quantum wells (QWs), on a GaAs substrate, within a metamorphic laser structure are correlated. The findings reveal significant inhomogeneities, particularly near the interfaces, for both the indium and strain distribution, and subtle variations in the Eg across individual QWs. The interplay between strain, composition, and Eg is further explored by density functional theory simulations, indicating that variations in the Eg are predominantly influenced by the indium concentration, with strain playing a minor role. The observed local inhomogeneities suggest that differences between individual QWs may affect the collective emission and performance of the final device. This study highlights the importance of spatially resolved analysis in understanding and optimizing the electronic and optical properties for designing next-generation metamorphic lasers with multiple QWs as the active region.

AB - Abstract Using high-resolution scanning transmission electron microscopy and low-loss electron energy loss spectroscopy, the local bandgap (Eg), indium concentration, and strain distribution across multiple InxGa1-xAs quantum wells (QWs), on a GaAs substrate, within a metamorphic laser structure are correlated. The findings reveal significant inhomogeneities, particularly near the interfaces, for both the indium and strain distribution, and subtle variations in the Eg across individual QWs. The interplay between strain, composition, and Eg is further explored by density functional theory simulations, indicating that variations in the Eg are predominantly influenced by the indium concentration, with strain playing a minor role. The observed local inhomogeneities suggest that differences between individual QWs may affect the collective emission and performance of the final device. This study highlights the importance of spatially resolved analysis in understanding and optimizing the electronic and optical properties for designing next-generation metamorphic lasers with multiple QWs as the active region.

KW - bandgap

KW - electron energy loss spectroscopy

KW - in concentration

KW - InGaAs

KW - quantum well

KW - strain distribution

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ER -

Evaluating the Local Bandgap Across inxGa1-xas Multiple Quantum Wells in a Metamorphic Laser via Low-Loss EELS

Abstract

Keywords

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Projects

SuperSTEM: National Research Facility for Advanced Electron Microscopy

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