Abstract
Simple, controllable models play an important role in learning how to manipulate and control quantum resources. We focus here on quantum non-Markovianity and model the evolution of open quantum systems by quantum renewal processes. This class of quantum dynamics provides us with a phenomenological approach to characterise dynamics with a variety of non-Markovian behaviours, here described in terms of the trace distance between two reduced states. By adopting a trajectory picture for the open quantum system evolution, we analyse how non-Markovianity is influenced by the constituents defining the quantum renewal process, namely the time-continuous part of the dynamics, the type of jumps and the waiting time distributions. We focus not only on the mere value of the non-Markovianity measure, but also on how different features of the trace distance evolution are altered, including times and number of revivals.
Highlights
IntroductionQuantum phenomena are deemed to be the main ingredients of the technological breakthroughs
Effects in Quantum DynamicsQuantum phenomena are deemed to be the main ingredients of the technological breakthroughs
By adopting a trajectory picture for the open quantum system evolution, we analyse how non-Markovianity is influenced by the constituents defining the quantum renewal process, namely the time-continuous part of the dynamics, the type of jumps and the waiting time distributions
Summary
Quantum phenomena are deemed to be the main ingredients of the technological breakthroughs. In the case of the quantum renewal processes that we analyse here, CPTP of the dynamical map is guaranteed by construction This makes this class of open quantum system dynamics a valuable tool for the phenomenological description of reduced dynamics. Despite their simplicity, quantum renewal processes can show a wide range of non-Markovian behaviours, which we analyse in details in the following.
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