Gamow vectors and Borel summability
Abstract
We analyze the detailed time dependence of the wave function for one dimensional Hamiltonians where (for example modeling barriers or wells) and are {\em compactly supported}. We show that the dispersive part of , its asymptotic series in powers of , is Borel summable. The remainder, the difference between and the Borel sum, is a convergent expansion of the form , where are the Gamow vectors of , and are the associated resonances; generically, all are nonzero. For large , . The effect of the Gamow vectors is visible when time is not very large, and the decomposition defines rigorously resonances and Gamow vectors in a nonperturbative regime, in a physically relevant way. The decomposition allows for calculating for moderate and large , to any prescribed exponential accuracy, using optimal truncation of power series plus finitely many Gamow vectors contributions. The analytic structure of is perhaps surprising: in general (even in simple examples such as square wells), turns out to be in but nowhere analytic on . In fact, is analytic in a sector in the lower half plane and has the whole of a natural boundary.
Cite
@article{arxiv.0902.0654,
title = {Gamow vectors and Borel summability},
author = {Ovidiu Costin and Min Huang},
journal= {arXiv preprint arXiv:0902.0654},
year = {2009}
}