The spin–lattice relaxation time of conduction electrons is calculated for III–V and II–VI zincblende semiconductors, where the conduction band is of Γ₆-symmetry. The electronic states are described within the Kane three-level model of band structure. Deformation potential interaction with acoustic and optical phonons, together with the piezo-acoustic and polar optical scattering modes are considered. The spin-flip transitions occur due to spin mixing in the electron wavefunctions (Elliott-Yafet mechanism). Numerical calculations show that the electron–phonon interaction provides an important channel of the spin relaxation at high temperatures.

Abstract

Es wird die Spin–Gitter-Relaxationszeit der Leitungselektronen für III–V- und II–VI-Zinkblende-halbleiter, wo das Leitungsband Γ₆-Symmetrie besitzt, berechnet. Die Elektronenzustände werden mit dem Drei-Niveau-Modell der Bandstruktur von Kane beschrieben. Deformationspotential-wechselwirkung mit akustischen und optischen Phononen, zusammen mit piezoakustischen und polaren optischen Streumoden werden berücksichtigt. Spin-Flip-Übergänge treten infolge von Spin-Mischung der Elektronenwellenfunktionen (Elliott-Yafet-Mechanismus) auf. Numerische Rechnungen zeigen, daß die Elektron–Phonon-Wechselwirkung einen wirksamen Kanal für Spin-Relaxation bei hohen Temperaturen bilden.

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Volume104, Issue1

1 March 1981

Pages 89-95

The Theory of the Electron Spin–Lattice Relaxation in Zincblende Semiconductors

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The Theory of the Electron Spin–Lattice Relaxation in Zincblende Semiconductors

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