Magnetic field dependence of the electron spin revival amplitude in periodically pulsed quantum dots.

Periodic laser pulsing of singly charged semiconductor quantum dots leads to a synchronization of the spin dynamics with the optical excitations. The Larmor precession of the optically oriented resident electron spins about an external magnetic field is frequency focused by the surrounding nuclear spins. The electron spin revival amplitude at the incidence time of each laser pulse is amplified by this additional mode-locking of the Overhauser field. Long sequences of pulses train the nuclear spin bath such that an integer or a half-integer number of electron spin revolutions between two subsequent pulses occur. We present experimental data of the non-monotonic revival amplitude as function of the external magnetic field. A quantum mechanical approach for the density operator of the coupled electron-nuclear spin system is developed that combines the effect of each pulse with the exact solution of the Lindblad equation for the dynamics between the pulses. The non-monotonic behavior of the revival amplitude is ascribed to a magnetic field dependent resonance condition for the Overhauser field distribution caused by the nuclear Zeeman effect. At large magnetic fields, we observe an interplay between the nuclear Larmor precession with the electron spin dynamics that favors one or the other electronic resonance condition after applying up to 20 million laser pulses in the simulation. This analysis is augmented by numerical calculations of classical spins subject to periodic pumping accounting for a large number of nuclear spins which confirm the link of the non-monotonic magnetic field behavior to the nuclear Zeeman precession.