Quantum loss of synchronization in the dynamics of two spins

Abstract

Motivated by the spin self-rephasing recently observed in an atomic clock, we introduce a simple dynamical model to study the competition between dephasing and synchronization. Two spins S are taken to be initially parallel and in the plane perpendicular to an inhomogeneous magnetic field that tends to dephase them. In addition, the spins are coupled by exchange interaction J that tries to keep them locked. The analytical solution of the classical dynamics shows that, there is a phase transition to a synchronized regime for sufficiently large exchange interaction J> compared to the inhomogeneity. The quantum dynamics is solved analytically in four limits -- large/small J/ and large/small S -- and numerically in between. In sharp contrast to the classical case, the quantum solution features very rich S-dependent multiscale dynamics. For any finite S, there is no synchronization but a crossover around J= between two regimes. The synchronization transition is only recovered when S ∞, approaching the classical solution in a non-trivial way. Quantum effects therefore suppress the synchronization transition.