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Main Authors: Li, Xinxin, Deng, Zhen, Jiang, Yang, Du, Chunhua, Jia, Haiqiang, Wang, Wenxin, Chen, Hong
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2405.10980
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author Li, Xinxin
Deng, Zhen
Jiang, Yang
Du, Chunhua
Jia, Haiqiang
Wang, Wenxin
Chen, Hong
author_facet Li, Xinxin
Deng, Zhen
Jiang, Yang
Du, Chunhua
Jia, Haiqiang
Wang, Wenxin
Chen, Hong
contents Quantum confinement is recognized to be an inherent property in low-dimensional structures. Traditionally it is believed that the carriers trapped within the well cannot escape due to the discrete energy levels. However, our previous research has revealed efficient carrier escape in low-dimensional structures, contradicting this conventional understanding. In this study, we review the energy band structure of quantum wells considering it as a superposition of the bulk material dispersion and quantization energy dispersion resulting from the quantum confinement across the whole Brillouin zone. By accounting for all wave vectors, we obtain a certain distribution of carrier energy at each quantization energy level, giving rise to the energy subbands. These results enable carriers to escape from the well under the influence of an electric field. Additionally, we have compiled a comprehensive summary of various energy band scenarios in quantum well structures, relevant to carrier transport. Such a new interpretation holds significant value in deepening our comprehension of low-dimensional energy bands, discovering new physical phenomena, and designing novel devices with superior performance.
format Preprint
id arxiv_https___arxiv_org_abs_2405_10980
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Research on the Quantum confinement of Carriers in the Type-I Quantum Wells Structure
Li, Xinxin
Deng, Zhen
Jiang, Yang
Du, Chunhua
Jia, Haiqiang
Wang, Wenxin
Chen, Hong
Mesoscale and Nanoscale Physics
Quantum Physics
Quantum confinement is recognized to be an inherent property in low-dimensional structures. Traditionally it is believed that the carriers trapped within the well cannot escape due to the discrete energy levels. However, our previous research has revealed efficient carrier escape in low-dimensional structures, contradicting this conventional understanding. In this study, we review the energy band structure of quantum wells considering it as a superposition of the bulk material dispersion and quantization energy dispersion resulting from the quantum confinement across the whole Brillouin zone. By accounting for all wave vectors, we obtain a certain distribution of carrier energy at each quantization energy level, giving rise to the energy subbands. These results enable carriers to escape from the well under the influence of an electric field. Additionally, we have compiled a comprehensive summary of various energy band scenarios in quantum well structures, relevant to carrier transport. Such a new interpretation holds significant value in deepening our comprehension of low-dimensional energy bands, discovering new physical phenomena, and designing novel devices with superior performance.
title Research on the Quantum confinement of Carriers in the Type-I Quantum Wells Structure
topic Mesoscale and Nanoscale Physics
Quantum Physics
url https://arxiv.org/abs/2405.10980