Quantum particle escape from a time-dependent confining potential
Abstract
Quantum escape of a particle via a time-dependent confining potential in a semi-infinite one-dimensional space is discussed. We describe the time-evolution of escape states in terms of scattering states of the quantum open system, and calculate the probability for a particle to remain in the confined region at time in the case of a delta-function potential with a time-oscillating magnitude. The probability decays exponentially in time at early times, then decays as a power later, along with a time-oscillation in itself. We show that a larger time-oscillation amplitude of the confining potential leads to a faster exponential decay of the probability , while it can rather enhance the probability decaying as a power. These contrastive behaviors of the probability in different types of decay are discussed quantitatively by using the decay time and the power decay magnitude of the probability .
Cite
@article{arxiv.1211.5212,
title = {Quantum particle escape from a time-dependent confining potential},
author = {Tooru Taniguchi and Shin-ichi Sawada},
journal= {arXiv preprint arXiv:1211.5212},
year = {2013}
}
Comments
13 pages, 5 figures