Coherent control based on quantum Zeno and anti-Zeno effects: Role of coherences and timing

Abstract: The quantum-Zeno and anti-Zeno effects (QZE/AZE) are known for a long time, in a quantum system with coupled levels, the measurement of a particular level population can lead to either acceleration (i.e. AZE) or retardation (i.e. QZE) of its population transfer to other levels. Here we consider how one can control the population flow from a coupled quantum state by measurement at a particular time, and what system parameters are responsible for that. We propose a framework for analysis of quantum Zeno dynamics based on time-dependent density matrix perturbation theory. This framework allows us to clearly separate state populations from their coherences and to predict appearance of either QZE or AZE. We illustrate our analysis on two model systems: 1) two coupled levels and 2) a level coupled to a continuum. In both cases dynamics of quantum coherences play a crucial role, and perturbative considerations allow us to predict the effect of projective measurements. In addition, we have extended our consideration to a closely related coherent control scenario, a unitary transformation flipping a sign of a state in a coherent superposition describing the system wavefunction.