Decay versus survival of a localized state subjected to harmonic forcing: exact results
Abstract
We investigate the survival probability of a localized 1-d quantum particle subjected to a time dependent potential of the form rU(x)ω t with U(x)=2δ (x-a) or U(x)= 2δ(x-a)-2δ (x+a). The particle is initially in a bound state produced by the binding potential -2δ (x). We prove that this probability goes to zero as t∞ for almost all values of r, ω, and a. The decay is initially exponential followed by a t-3 law if ω is not close to resonances and r is small; otherwise the exponential disappears and Fermi's golden rule fails. For exceptional sets of parameters r,ω and a the survival probability never decays to zero, corresponding to the Floquet operator having a bound state. We show similar behavior even in the absence of a binding potential: permitting a free particle to be trapped by harmonically oscillating delta function potential.
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