Open AccessQuantum confinement and band offsets in amorphous silicon quantum wells
Author(s) -
Karol Jarolimek,
R. A. de Groot,
G. A. de Wijs,
Miro Zeman
Publication year - 2014
Publication title -
physical review b
Language(s) - English
Resource type - Journals
eISSN - 1538-4489
pISSN - 1098-0121
DOI - 10.1103/physrevb.90.125430
Subject(s) - quantum well , condensed matter physics , quantum dot , amorphous solid , materials science , band gap , potential well , amorphous silicon , electronic band structure , semiconductor , silicon , physics , optoelectronics , crystalline silicon , quantum mechanics , chemistry , laser , organic chemistry
Quantum wells (QWs) are nanostructures consisting of alternating layers of a low and high band-gap semiconductor. The band gap of QWs can be tuned by changing the thickness of the low band-gap layer, due to quantum confinement effects. Although this principle is well established for crystalline materials, there is still controversy for QWs fabricated from amorphous materials: How strong are the confinement effects in amorphous QWs, where, because of the disorder, the carriers are localized to start with? We prepare an atomistic model of QWs based on a-Si:H to gain insight into this problem. The electronic structure of our atomistic QWs model is described with first-principles density functional theory, allowing us to study the confinement effects directly. We find that the quantum confinement effect is rather weak, compared to experimental results on a similar system
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