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Main Authors: Kazakov, Alexander, Krizman, Gauthier, Volobuev, Valentine V., Szot, Michał, Wołkanowicz, Wojciech, Cho, Chang-Woo, Piot, Benjamin A., Wojciechowski, Tomasz, Springholz, Gunther, Wojtowicz, Tomasz, Dietl, Tomasz
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.19025
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author Kazakov, Alexander
Krizman, Gauthier
Volobuev, Valentine V.
Szot, Michał
Wołkanowicz, Wojciech
Cho, Chang-Woo
Piot, Benjamin A.
Wojciechowski, Tomasz
Springholz, Gunther
Wojtowicz, Tomasz
Dietl, Tomasz
author_facet Kazakov, Alexander
Krizman, Gauthier
Volobuev, Valentine V.
Szot, Michał
Wołkanowicz, Wojciech
Cho, Chang-Woo
Piot, Benjamin A.
Wojciechowski, Tomasz
Springholz, Gunther
Wojtowicz, Tomasz
Dietl, Tomasz
contents The ability to tune the Fermi level of semiconductors is at the heart of modern electronics. Here, we demonstrate that persistent photoconductivity (PPC) enables tuning of carrier density, conductivity type, and, consequently, the valley polarization in (Pb,Sn)Se/(Pb,Eu)Se quantum wells. Illumination of these samples induces Fermi level shifts that convert the system from a threefold-degenerate $\bar{M}$-valley two-dimensional hole gas to a single $\barΓ$-valley-polarized electron gas with similar values of mobility. The optically induced state persists for more than $10^{3}$ minutes at cryogenic temperatures and enables stepwise optical gating without the need for device processing. These transitions are confirmed by the sign inversion of the Hall slope and the modification of quantum Hall plateau degeneracies measured in magnetic fields up to 35 T. Landau level $k\cdot p$ model calculations quantitatively reproduce the experimental data. Furthermore, studies of weak-field magnetoresistance demonstrate the significance of quantum localization phenomena at the transition between the weakly and strongly localized regimes in compensated narrow-gap semiconductors. Spectral studies allow us to identify the critical role of the barrier material and determine the photon energies that can reverse the PPC effect. The persistent light-induced upward shift of the Fermi level in the $p$-type quantum well is explained in terms of specific energy positions of donor and acceptor defect states in the studied system. Our results demonstrate that PPC is a powerful optical gating tool for the IV-VI quantum wells, a versatile platform for reconfigurable valleytronic architectures.
format Preprint
id arxiv_https___arxiv_org_abs_2605_19025
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Optical control of conductivity type and valley polarization via persistent photoconductivity in (Pb,Sn)Se quantum wells
Kazakov, Alexander
Krizman, Gauthier
Volobuev, Valentine V.
Szot, Michał
Wołkanowicz, Wojciech
Cho, Chang-Woo
Piot, Benjamin A.
Wojciechowski, Tomasz
Springholz, Gunther
Wojtowicz, Tomasz
Dietl, Tomasz
Mesoscale and Nanoscale Physics
Materials Science
The ability to tune the Fermi level of semiconductors is at the heart of modern electronics. Here, we demonstrate that persistent photoconductivity (PPC) enables tuning of carrier density, conductivity type, and, consequently, the valley polarization in (Pb,Sn)Se/(Pb,Eu)Se quantum wells. Illumination of these samples induces Fermi level shifts that convert the system from a threefold-degenerate $\bar{M}$-valley two-dimensional hole gas to a single $\barΓ$-valley-polarized electron gas with similar values of mobility. The optically induced state persists for more than $10^{3}$ minutes at cryogenic temperatures and enables stepwise optical gating without the need for device processing. These transitions are confirmed by the sign inversion of the Hall slope and the modification of quantum Hall plateau degeneracies measured in magnetic fields up to 35 T. Landau level $k\cdot p$ model calculations quantitatively reproduce the experimental data. Furthermore, studies of weak-field magnetoresistance demonstrate the significance of quantum localization phenomena at the transition between the weakly and strongly localized regimes in compensated narrow-gap semiconductors. Spectral studies allow us to identify the critical role of the barrier material and determine the photon energies that can reverse the PPC effect. The persistent light-induced upward shift of the Fermi level in the $p$-type quantum well is explained in terms of specific energy positions of donor and acceptor defect states in the studied system. Our results demonstrate that PPC is a powerful optical gating tool for the IV-VI quantum wells, a versatile platform for reconfigurable valleytronic architectures.
title Optical control of conductivity type and valley polarization via persistent photoconductivity in (Pb,Sn)Se quantum wells
topic Mesoscale and Nanoscale Physics
Materials Science
url https://arxiv.org/abs/2605.19025