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Full Salpeter Equation with Confining Interactions: Analytic Stability Proof

High Energy Physics - Phenomenology 2009-06-25 v1

Abstract

The most popular 3-dimensional reduction of the Bethe-Salpeter formalism for the description of bound states within quantum field theory is the Salpeter equation, found as the instantaneous limit of the Bethe-Salpeter framework if allowing, in addition, for free propagation of the bound-state constituents. Unfortunately, depending on the Lorentz nature of the Bethe-Salpeter kernel, supposedly stable results of Salpeter's equation with confining interactions exhibit (un-)expected instabilities, probably related to Klein's paradox. Clearly, bound states may be regarded as stable if, for appropriate interactions, their mass eigenvalues belong to a real and discrete (part of the) spectrum that is bounded from below. Some general features of the eigenvalue spectra of any Salpeter equation are well-established: all bound-state masses squared are real and, for a large class of sufficiently reasonable Bethe-Salpeter kernels - which includes all interactions of phenomenological relevance for QCD -, the spectrum of mass eigenvalues consists, in the complex bound-state mass plane, at most of real pairs of opposite sign and imaginary points. For time-component vector harmonic-oscillator kernels, a straightforward stability proof is given.

Keywords

Cite

@article{arxiv.0810.5500,
  title  = {Full Salpeter Equation with Confining Interactions: Analytic Stability Proof},
  author = {Wolfgang Lucha},
  journal= {arXiv preprint arXiv:0810.5500},
  year   = {2009}
}

Comments

to appear in the proceedings of the 8th Conference on Quark Confinement and the Hadron Spectrum

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