The effect of measurements, randomly distributed in time, on quantum systems. Stochastic quantum Zeno effect

TL;DR

This paper investigates how randomly timed measurements influence quantum system evolution, modeling the process with renewal theory and analyzing effects like quantum and inverse Zeno phenomena through different statistical distributions.

Contribution

It introduces a stochastic Liouville equation framework for RDM and explores its impact on two-level quantum systems with various measurement timing distributions.

Findings

RDM affects quantum evolution significantly.

Poissonian and anomalous measurement statistics produce distinct Zeno effects.

Theoretical analysis clarifies conditions for quantum and inverse Zeno phenomena.

Abstract

The manifestation of measurements, randomly distributed in time, on the evolution of quantum systems are analyzed in detail. The set of randomly distributed measurements (RDM) is modeled within the renewal theory, in which the distribution is characterized by the probability density function (PDF) W(t) of times t between successive events (measurements). The evolution of the quantum system affected by the RDM is shown to be described by the density matrix satisfying the stochastic Liouville equation. This equation is applied to the analysis of the RDM effect on the evolution of a two level systems for different types of RDM statistics, corresponding to different PDFs W(t). Obtained general results are illustrated as applied to the cases of the Poissonian [W(t) ~ e^{-w_r t}] and anomalous [W(t) ~ 1/t^{1+\alpha}, (\alpha is smaller or equal to 1)], RDM statistics. In particular, specific features of the quantum and inverse Zeno effects, resulting from the RDM, are thoroughly discussed.