# Unphysical energy sheets and resonances in the Friedrichs-Faddeev model

**Authors:** Alexander K. Motovilov

arXiv: 1812.08291 · 2019-10-09

## TL;DR

This paper analyzes the Friedrichs-Faddeev model with holomorphic kernels, exploring the structure of scattering matrices on unphysical sheets and establishing a link between deformation resonances and scattering matrix poles.

## Contribution

It provides explicit representations of the $T$- and $S$-matrices on unphysical sheets and proves the correspondence between deformation resonances and scattering matrix poles for analytic potentials.

## Key findings

- Explicit formulas for $T$- and $S$-matrices on unphysical sheets
- Deformation resonances correspond to poles of the analytically continued scattering matrix
- Resonance structures are characterized through complex deformation of the Hamiltonian

## Abstract

We consider the Friedrichs-Faddeev model in the case where the kernel of the potential operator is holomorphic in both arguments on a certain domain of $\mathbb{C}$. For this model we, first, study the structure of the $T$- and $S$-matrices on unphysical energy sheet(s). To this end, we derive representations that explicitly express them in terms of these same operators considered exclusively on the physical sheet. Furthermore, we allow the Friedrichs-Faddeev Hamiltonian undergo a complex deformation (or even a complex scaling/rotation if the model is associated with an infinite interval). Isolated non-real eigenvalues of the deformed Hamiltonian are called the deformation resonances. For a class of perturbation potentials with analytic kernels, we prove that the deformation resonances do correspond to the scattering matrix resonances, that is, they represent the poles of the scattering matrix analytically continued to the respective unphysical sheet.

## Full text

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## Figures

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## References

18 references — full list in the complete paper: https://tomesphere.com/paper/1812.08291/full.md

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Source: https://tomesphere.com/paper/1812.08291