Electron spin quantum beats in positively charged quantum dots: nuclear field effects

TL;DR

This study investigates electron spin coherence in positively charged quantum dots, highlighting nuclear field fluctuations and g-factor dispersion as key factors affecting spin dephasing, supported by a model aligning with experimental data.

Contribution

The paper presents a comprehensive model that accounts for nuclear and inhomogeneity effects on electron spin dephasing in quantum dots, matching experimental observations.

Findings

Nuclear field fluctuations significantly contribute to spin dephasing.

g-factor dispersion causes field-dependent damping of spin oscillations.

The model accurately predicts experimental damping behavior.

Abstract

We have studied the electron spin coherence in an ensemble of positively charged InAs/GaAs quantum dots. In a transverse magnetic field, we show that two main contributions must be taken into account to explain the damping of the circular polarization oscillations. The first one is due to the nuclear field fluctuations from dot to dot experienced by the electron spin. The second one is due to the dispersion of the transverse electron Lande g-factor, due to the inherent inhomogeneity of the system, and leads to a field dependent contribution to the damping. We have developed a model taking into account both contributions, which is in good agreement with the experimental data. This enables us to extract the pure contribution to dephasing due to the nuclei.