Your search keyword '"Ben, Teresa"' showing total 4 results

1. Exploring the Implementation of GaAsBi Alloys as Strain-Reducing Layers in InAs/GaAs Quantum Dots.

Author

Braza, Verónica, Fernández, Daniel, Ben, Teresa, Flores, Sara, Bailey, Nicholas James, Carr, Matthew, Richards, Robert, and Gonzalez, David

Subjects

AUDITING standards, GALLIUM arsenide, LOW temperatures, ALLOYS, NANOPARTICLES, QUANTUM dots, NANOWIRES

Abstract

This paper investigates the effect of GaAsBi strain reduction layers (SRLs) on InAs QDs with different Bi fluxes to achieve nanostructures with improved temperature stability. The SRLs are grown at a lower temperature (370 °C) than the usual capping temperature for InAs QDs (510 °C). The study finds that GaAs capping at low temperatures reduces QD decomposition and leads to larger pyramidal dots but also increases the threading dislocation (TD) density. When adding Bi to the capping layer, a significant reduction in TD density is observed, but unexpected structural changes also occur. Increasing the Bi flux does not increase the Bi content but rather the layer thickness. The maximum Bi content for all layers is 2.4%. A higher Bi flux causes earlier Bi incorporation, along with the formation of an additional InGaAs layer above the GaAsBi layer due to In segregation from QD erosion. Additionally, the implementation of GaAsBi SRLs results in smaller dots due to enhanced QD decomposition, which is contrary to the expected function of an SRL. No droplets were detected on the surface of any sample, but we did observe regions of horizontal nanowires within the epilayers for the Bi-rich samples, indicating nanoparticle formation. [ABSTRACT FROM AUTHOR]

Published

2024

2. Modification of the optical and structural properties of ZnO nanowires by low-energy Ar+ ion sputtering

Author

Allah, Rabie Fath, Ben, Teresa, González, David, Hortelano, Vanesa, Martínez, Oscar, and Plaza, Jose Luis

Published

2013

3. Modification of the optical and structural properties of ZnO nanowires by low-energy Ar+ ion sputtering.

Author

Allah, Rabie Fath, Ben, Teresa, González, David, Hortelano, Vanesa, Martínez, Oscar, and Plaza, Jose Luis

Subjects

NANOWIRES, ARGININE, SPUTTERING (Physics), OPTICAL properties of zinc oxide, CHEMICAL structure

Abstract

The effects of low-energy (⩽2 kV) Ar+ irradiation on the optical and structural properties of zinc oxide (ZnO) nanowires (NWs) grown by a simple and cost-effective low-temperature technique were investigated. Both photoluminescence spectra from ZnO NW-coated films and cathodoluminescence analysis of individual ZnO NWs demonstrated obvious evidences of ultraviolet/visible luminescent enhancement with respect to irradiation fluence. Annihilation of the thinner ZnO NWs after the ion bombardment was appreciated by means of high-resolution scanning electron microscopy and transmission electron microscopy (TEM), which results in an increasing NW mean diameter for increasing irradiation fluences. Corresponding structural analysis by TEM pointed out not only significant changes in the morphology but also in the microstructure of these NWs, revealing certain radiation-sensitive behavior. The possible mechanisms accounting for the decrease of the deep-level emissions in the NWs with the increasing irradiation fluences are discussed according to their structural modifications. [ABSTRACT FROM AUTHOR]

Published

2013

4. Size control of InAs/InP(001) quantum wires by tailoring P/As exchange.

Author

Fuster, David, González, Marí Ujué, González, Luisa, González, Yolanda, Ben, Teresa, Ponce, Arturo, Molina, Sergio I., and Martínez-Pastor, Juan

Subjects

NANOWIRES, ARSENIC, NATIVE element minerals, ELECTRIC wire, NANOSTRUCTURED materials, NANOTECHNOLOGY

Abstract

The size and emission wavelength of self-assembled InAs/InP(001) quantum wires (QWrs) is affected by the P/As exchange process. In this work, we demonstrate by in situ stress measurements that P/As exchange at the InAs/InP interface depends on the surface reconstruction of the InAs starting surface and its immediate evolution when the arsenic cell is closed. Accordingly, the amount of InP grown on InAs by P/As exchange increases with substrate temperature in a steplike way. These results allow us to engineer the size of the QWr for emission at 1.3 and 1.55 μm at room temperature by selecting the range of substrate temperatures in which the InP cap layer is grown. [ABSTRACT FROM AUTHOR]

Published

2004