Quantum walks: the first detected transition time
Abstract
We consider the quantum first detection problem for a particle evolving on a graph under repeated projective measurements with fixed rate . A general formula for the mean first detected transition time is obtained for a quantum walk in a finite-dimensional Hilbert space where the initial state of the walker is orthogonal to the detected state . We focus on diverging mean transition times, where the total detection probability exhibits a discontinuous drop of its value, by mapping the problem onto a theory of fields of classical charges located on the unit disk. Close to the critical parameter of the model, which exhibits a blow-up of the mean transition time, we get simple expressions for the mean transition time. Using previous results on the fluctuations of the return time, corresponding to , we find close to these critical parameters that the mean transition time is proportional to the fluctuations of the return time, an expression reminiscent of the Einstein relation.
Cite
@article{arxiv.2001.00231,
title = {Quantum walks: the first detected transition time},
author = {Q. Liu and R. Yin and K. Ziegler and E. Barkai},
journal= {arXiv preprint arXiv:2001.00231},
year = {2020}
}