Krzysztof Gawarecki, Jakub Ziembicki, Paweł Scharoch, Robert Kudrawiec
Published 2023-11-30Version 1
In this paper, we study theoretically the electron and spectral properties of Ge1-xSnx systems, including alloys, cubic- and spherical quantum dots. The single-particle electron and hole states are calculated within the sp3d5s* tight-binding approach and used in further modeling of the optical properties. We systematically study the interplay of Sn-driven indirect-direct band-gap transition and the quantum confinement effect in systems of reduced dimensionality. We demonstrate the regime of sizes and composition, where the ground state in Ge1-xSnx quantum dot is optically active. Finally, we calculate absorbance spectra in experimentally-relevant colloidal quantum dots and demonstrate a satisfactory agreement with experimental data.
The Signs of Quantum Dot-Lead Matrix Elements: The Effect on Transport vs. Spectral Properties
Spectral Properties of Three Dimensional Layered Quantum Hall Systems
Spectral Properties and Local Density of States of Disordered Quantum Hall Systems with Rashba Spin-Orbit Coupling
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