Two-dimensional magnetoexciton-polariton in semiconductor microcavity

Moskalenko Sveatoslav; Podlesny Igor; Liberman Michael; Novikov Boris; Kiselyova E.

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MOSKALENKO, Sveatoslav, PODLESNY, Igor, LIBERMAN, Michael, NOVIKOV, Boris, KISELYOVA, E.. Two-dimensional magnetoexciton-polariton in semiconductor microcavity. In: Nanotechnologies and Biomedical Engineering, Ed. 2, 18-20 aprilie 2013, Chișinău. Technical University of Moldova, 2013, Editia 2, pp. 180-184. ISBN 978-9975-62-343-8..

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Nanotechnologies and Biomedical Engineering
Editia 2, 2013

Conferința "International Conference on Nanotechnologies and Biomedical Engineering"
2, Chișinău, Moldova, 18-20 aprilie 2013

Two-dimensional magnetoexciton-polariton in semiconductor microcavity

Pag. 180-184

Moskalenko Sveatoslav¹, Podlesny Igor¹, Liberman Michael², Novikov Boris³, Kiselyova E.⁴

¹ Institute of Applied Physics, Academy of Sciences of Moldova,
² Uppsala University,
³ Saint Petersburg State University,
⁴ Moldova State University

Disponibil în IBN: 17 iunie 2019

Rezumat

The Hamiltonian describing the interaction of the two-dimensional (2D) magnetoexcitons with photons propagating with arbitrary oriented wave vectors in the three-dimensional (3D) space was deduced. The magnetoexcitons are characterized by the numbers e n and h n of the electron and hole Landau quantizations, by circular polarization M  of the holes in the p -type valence bands and by in-plane wave vectors || k . The photons are characterized by the wave vectors k with in-plane component || k and perpendicular component z k which is quantized in the case of microresonator. The interaction is governed by the conservation law of the in-plane components || k of the magnetoexcitons and photons and by the rotational symmetry around the axis perpendicular to the layer which leads to the alignment of the magnetoexcitons under the influence of the photons with circular polarization k   and with probability proportional to   2 * · .

Cuvinte-cheie
magnetoexciton, polariton, two-dimensional electron-hole system

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