English

Gamow vectors and Borel summability

Mathematical Physics 2009-02-05 v1 Analysis of PDEs math.MP

Abstract

We analyze the detailed time dependence of the wave function ψ(x,t)\psi(x,t) for one dimensional Hamiltonians H=x2+V(x)H=-\partial_x^2+V(x) where VV (for example modeling barriers or wells) and ψ(x,0)\psi(x,0) are {\em compactly supported}. We show that the dispersive part of ψ(x,t)\psi(x,t), its asymptotic series in powers of t1/2t^{-1/2}, is Borel summable. The remainder, the difference between ψ\psi and the Borel sum, is a convergent expansion of the form k=0gkΓk(x)eγkt\sum_{k=0}^{\infty}g_k \Gamma_k(x)e^{-\gamma_k t}, where Γk\Gamma_k are the Gamow vectors of HH, and γk\gamma_k are the associated resonances; generically, all gkg_k are nonzero. For large kk, γkconstklogk+k2π2i/4\gamma_{k}\sim const\cdot k\log k +k^2\pi^{2}i/4. 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 ψ\psi for moderate and large tt, to any prescribed exponential accuracy, using optimal truncation of power series plus finitely many Gamow vectors contributions. The analytic structure of ψ\psi is perhaps surprising: in general (even in simple examples such as square wells), ψ(x,t)\psi(x,t) turns out to be CC^\infty in tt but nowhere analytic on \RR+\RR^+. In fact, ψ\psi is tt-analytic in a sector in the lower half plane and has the whole of \RR+\RR^+ 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}
}
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