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Renormalization of the electron g factor in the degenerate two-dimensional electron gas of ZnSe- and CdTe-based quantum wells. / Zhukov, E.A.; Mantsevich, V. N.; Yakovlev, D.R.; Kopteva, N. E. ; Kirstein, E.; Waag, A.; Karczewski, G.; Wojtowicz, Tomasz; Bayer, M.

в: Physical Review B-Condensed Matter, Том 102, 125306, 18.09.2020.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

Harvard

Zhukov, EA, Mantsevich, VN, Yakovlev, DR, Kopteva, NE, Kirstein, E, Waag, A, Karczewski, G, Wojtowicz, T & Bayer, M 2020, 'Renormalization of the electron g factor in the degenerate two-dimensional electron gas of ZnSe- and CdTe-based quantum wells', Physical Review B-Condensed Matter, Том. 102, 125306.

APA

Zhukov, E. A., Mantsevich, V. N., Yakovlev, D. R., Kopteva, N. E., Kirstein, E., Waag, A., Karczewski, G., Wojtowicz, T., & Bayer, M. (2020). Renormalization of the electron g factor in the degenerate two-dimensional electron gas of ZnSe- and CdTe-based quantum wells. Physical Review B-Condensed Matter, 102, [125306].

Vancouver

Zhukov EA, Mantsevich VN, Yakovlev DR, Kopteva NE, Kirstein E, Waag A и пр. Renormalization of the electron g factor in the degenerate two-dimensional electron gas of ZnSe- and CdTe-based quantum wells. Physical Review B-Condensed Matter. 2020 Сент. 18;102. 125306.

Author

Zhukov, E.A. ; Mantsevich, V. N. ; Yakovlev, D.R. ; Kopteva, N. E. ; Kirstein, E. ; Waag, A. ; Karczewski, G. ; Wojtowicz, Tomasz ; Bayer, M. / Renormalization of the electron g factor in the degenerate two-dimensional electron gas of ZnSe- and CdTe-based quantum wells. в: Physical Review B-Condensed Matter. 2020 ; Том 102.

BibTeX

@article{ca0b76a64ee54bf0906b7be50c3a7ebd,
title = "Renormalization of the electron g factor in the degenerate two-dimensional electron gas of ZnSe- and CdTe-based quantum wells",
abstract = "The effective electron g factor, geff, is measured in a two-dimensional electron gas (2DEG) in modulation-doped ZnSe- and CdTe-based quantum wells by means of time-resolved pump-probe Kerr rotation. The measurements are performed in magnetic fields applied in the Voigt geometry, i.e., normal to the optical axis parallel to the quantum well plane, in the field range 0.05–6 T at temperatures 1.8–50K. The geff absolute value considerably increases with increasing electron density ne. geff changes in the ZnSe-based QWs from +1.1 to +1.9 in the ne range 3×1010−1.4×1012cm−2 and in the CdTe-based QWs from −1.55 down to −1.76 in the ne range 5×109−3×1011cm−2. The modification of geff reduces with increasing magnetic field, increasing temperature of lattice and 2DEG, the latter achieved by a higher photoexcitation density. A theoretical model is developed that considers the renormalization of the spin-orbit coupling constant of the two-dimensional electrons by the electron-electron interaction and takes into account corrections to the electron-electron interaction in the Hubbard form. The model results are in good agreement with experimental data.",
author = "E.A. Zhukov and Mantsevich, {V. N.} and D.R. Yakovlev and Kopteva, {N. E.} and E. Kirstein and A. Waag and G. Karczewski and Tomasz Wojtowicz and M. Bayer",
year = "2020",
month = sep,
day = "18",
language = "English",
volume = "102",
journal = "Physical Review B-Condensed Matter",
issn = "1098-0121",
publisher = "American Physical Society",

}

RIS

TY - JOUR

T1 - Renormalization of the electron g factor in the degenerate two-dimensional electron gas of ZnSe- and CdTe-based quantum wells

AU - Zhukov, E.A.

AU - Mantsevich, V. N.

AU - Yakovlev, D.R.

AU - Kopteva, N. E.

AU - Kirstein, E.

AU - Waag, A.

AU - Karczewski, G.

AU - Wojtowicz, Tomasz

AU - Bayer, M.

PY - 2020/9/18

Y1 - 2020/9/18

N2 - The effective electron g factor, geff, is measured in a two-dimensional electron gas (2DEG) in modulation-doped ZnSe- and CdTe-based quantum wells by means of time-resolved pump-probe Kerr rotation. The measurements are performed in magnetic fields applied in the Voigt geometry, i.e., normal to the optical axis parallel to the quantum well plane, in the field range 0.05–6 T at temperatures 1.8–50K. The geff absolute value considerably increases with increasing electron density ne. geff changes in the ZnSe-based QWs from +1.1 to +1.9 in the ne range 3×1010−1.4×1012cm−2 and in the CdTe-based QWs from −1.55 down to −1.76 in the ne range 5×109−3×1011cm−2. The modification of geff reduces with increasing magnetic field, increasing temperature of lattice and 2DEG, the latter achieved by a higher photoexcitation density. A theoretical model is developed that considers the renormalization of the spin-orbit coupling constant of the two-dimensional electrons by the electron-electron interaction and takes into account corrections to the electron-electron interaction in the Hubbard form. The model results are in good agreement with experimental data.

AB - The effective electron g factor, geff, is measured in a two-dimensional electron gas (2DEG) in modulation-doped ZnSe- and CdTe-based quantum wells by means of time-resolved pump-probe Kerr rotation. The measurements are performed in magnetic fields applied in the Voigt geometry, i.e., normal to the optical axis parallel to the quantum well plane, in the field range 0.05–6 T at temperatures 1.8–50K. The geff absolute value considerably increases with increasing electron density ne. geff changes in the ZnSe-based QWs from +1.1 to +1.9 in the ne range 3×1010−1.4×1012cm−2 and in the CdTe-based QWs from −1.55 down to −1.76 in the ne range 5×109−3×1011cm−2. The modification of geff reduces with increasing magnetic field, increasing temperature of lattice and 2DEG, the latter achieved by a higher photoexcitation density. A theoretical model is developed that considers the renormalization of the spin-orbit coupling constant of the two-dimensional electrons by the electron-electron interaction and takes into account corrections to the electron-electron interaction in the Hubbard form. The model results are in good agreement with experimental data.

UR - https://journals.aps.org/prb/abstract/10.1103/PhysRevB.102.125306

M3 - Article

VL - 102

JO - Physical Review B-Condensed Matter

JF - Physical Review B-Condensed Matter

SN - 1098-0121

M1 - 125306

ER -

ID: 62342704