Quantum dynamics of large spins in static and rotating magnetic fields: Entanglement resonances and kinks
Abstract
We examine the quantum dynamics of a large spin in the presence of static and rotating magnetic fields. By mapping the system onto a gas of non-interacting spin-1/2 particles, we derive exact analytical results for the dynamics with different initial states. The dynamics exhibit periodic oscillations between two maximally stretched states, irrespective of how large the spin is. Further, we observe periodic transitions between sublevels with magnetic quantum numbers of opposite signs. Additionally, the dynamics features the periodic transfer of the spin to the maximally stretched state starting from a superposition state. The evolution of the dipole moment is also explored in each case, and as expected, it is precessing about the instantaneous, resultant magnetic field. Furthermore, we extend our analysis to a pair of spins, taking into account the dipole-dipole interactions between them. We analyze how the ground state entanglement between the spins depends on the external fields. The quantum dynamics of the two spins reveal entanglement resonances and kinks, which can be identified from the energy spectrum when weak transverse field strengths are considered. Finally, we discuss the regime in which the dipolar interactions are relatively weak.