1. Stationary Scattering Theory for One-body Stark Operators, II
- Author
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Erik Skibsted and Kenichi Ito
- Subjects
Physics ,Nuclear and High Energy Physics ,Matrix (mathematics) ,Operator (computer programming) ,Kernel (image processing) ,Scattering ,Phase space ,Microlocal analysis ,Statistical and Nonlinear Physics ,Scattering theory ,Uniqueness ,Mathematical Physics ,Mathematical physics - Abstract
We study and develop the stationary scattering theory for a class of one-body Stark Hamiltonians with short-range potentials, including the Coulomb potential, continuing our study in Adachi et al. (JDE 268: 5179–5206, 2020; Stationary scattering theory for 1-body Stark operators). The classical scattering orbits are parabolas parametrized by asymptotic orthogonal momenta, and the kernel of the (quantum) scattering matrix at a fixed energy is defined in these momenta. We show that the scattering matrix is a classical type pseudodifferential operator and compute the leading order singularities at the diagonal of its kernel. Our approach can be viewed as an adaption of the method of Isozaki-Kitada (Tokyo Univ. 35: 81–107, 1985) used for studying the scattering matrix for one-body Schrödinger operators without an external potential. It is more flexible and more informative than the more standard method used previously by Kvitsinsky-Kostrykin (Teoret. Mat. Fiz. 75(3): 416-430, 1988) for computing the leading order singularities of the kernel of the scattering matrix in the case of a constant external field (the Stark case). Our approach relies on Sommerfeld’s uniqueness result in Besov spaces, microlocal analysis as well as on classical phase space constructions.
- Published
- 2021