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Influence of a magnetic field and temperature on the oscillations of the combined density of states in two-dimensional semiconductor materials

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Abstract

In this work, the dependence of the oscillation of the combined density of states on a strong magnetic field in heterostructures based on a rectangular quantum well is studied. The effect of a quantizing magnetic field on the temperature dependence of the combined density of states in nanoscale straight-band heterostructures is investigated. A new mathematical model has been developed for calculating the temperature dependence of the two-dimensional combined density of quantum well states in quantizing magnetic fields. The proposed model explains the experimental results in nanoscale straight-band semiconductors with a parabolic dispersion law.

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Authors and Affiliations

  1. Namangan Institute of Engineering and Technology, 160115, Namangan, Uzbekistan

    U. I. Erkaboev, R. G. Rakhimov, J. I. Mirzaev, U. M. Negmatov & N. A. Sayidov

  2. Namangan Engineering - Construction Institute, 160103, Namangan, Uzbekistan

    R. G. Rakhimov

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  1. U. I. Erkaboev
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  2. R. G. Rakhimov
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  3. J. I. Mirzaev
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  4. U. M. Negmatov
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  5. N. A. Sayidov
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Correspondence to U. I. Erkaboev.

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Erkaboev, U.I., Rakhimov, R.G., Mirzaev, J.I. et al. Influence of a magnetic field and temperature on the oscillations of the combined density of states in two-dimensional semiconductor materials. Indian J Phys 98, 189–197 (2024). https://doi.org/10.1007/s12648-023-02803-y

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  • DOI: https://doi.org/10.1007/s12648-023-02803-y

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