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Main Authors: Braza, V., Ben, T., Flores, S., Reyes, D. F., Gallego-Carro, A., Stanojevic, L., Gacevic, Z., Ruíz-Marín, N., Ulloa, J. M., González, D.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2401.17965
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author Braza, V.
Ben, T.
Flores, S.
Reyes, D. F.
Gallego-Carro, A.
Stanojevic, L.
Gacevic, Z.
Ruíz-Marín, N.
Ulloa, J. M.
González, D.
author_facet Braza, V.
Ben, T.
Flores, S.
Reyes, D. F.
Gallego-Carro, A.
Stanojevic, L.
Gacevic, Z.
Ruíz-Marín, N.
Ulloa, J. M.
González, D.
contents Recently, GaAsSb/GaAsN type II short-period superlattices (SLs) have been proposed as suitable structures to be implemented in the optimal design of monolithic multi-junction solar cells. However, due to strong surface Sb segregation, experimental Sb composition profiles differ greatly from the nominal square-wave design. In this work, the improvement of the interface quality of these SLs in terms of compositional abruptness and surface roughness has been evaluated by implementing different growth interruption times under Sb4/As4 (soaking) and As4 (desorption) overpressure conditions before and after the growth of GaAsSb layers, respectively. The combined effects of both processes enhance Sb distribution, achieving squarer compositional profiles with reduced surface roughness interfaces. It has been found that the improvement in compositional abruptness is quantitatively much higher at the lower interface, during soaking, than at the upper interface during desorption. Conversely, a larger decrease in surface roughness is achieved at the upper interface than at the lower interface. Fitting of the Sb segregation profiles using the 3-layer kinetic fluid model has shown that the increase in Sb incorporation rate is due to the decrease in segregation energy, presumably to changes in the surface reconstruction of the floating layer at the surface.
format Preprint
id arxiv_https___arxiv_org_abs_2401_17965
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Growth interruption strategies for interface optimization in GaAsSb/GaAsN type-II superlattices
Braza, V.
Ben, T.
Flores, S.
Reyes, D. F.
Gallego-Carro, A.
Stanojevic, L.
Gacevic, Z.
Ruíz-Marín, N.
Ulloa, J. M.
González, D.
Materials Science
Recently, GaAsSb/GaAsN type II short-period superlattices (SLs) have been proposed as suitable structures to be implemented in the optimal design of monolithic multi-junction solar cells. However, due to strong surface Sb segregation, experimental Sb composition profiles differ greatly from the nominal square-wave design. In this work, the improvement of the interface quality of these SLs in terms of compositional abruptness and surface roughness has been evaluated by implementing different growth interruption times under Sb4/As4 (soaking) and As4 (desorption) overpressure conditions before and after the growth of GaAsSb layers, respectively. The combined effects of both processes enhance Sb distribution, achieving squarer compositional profiles with reduced surface roughness interfaces. It has been found that the improvement in compositional abruptness is quantitatively much higher at the lower interface, during soaking, than at the upper interface during desorption. Conversely, a larger decrease in surface roughness is achieved at the upper interface than at the lower interface. Fitting of the Sb segregation profiles using the 3-layer kinetic fluid model has shown that the increase in Sb incorporation rate is due to the decrease in segregation energy, presumably to changes in the surface reconstruction of the floating layer at the surface.
title Growth interruption strategies for interface optimization in GaAsSb/GaAsN type-II superlattices
topic Materials Science
url https://arxiv.org/abs/2401.17965