Nabile Boussaid, Andrew Comech
Published 2012-11-14, updated 2015-07-24Version 2
We study the point spectrum of the nonlinear Dirac equation in any spatial dimension, linearized at one of the solitary wave solutions. We prove that, in any dimension, the linearized equation has no embedded eigenvalues in the part of the essential spectrum beyond the embedded thresholds. We then prove that the birth of point eigenvalues with nonzero real part (the ones which lead to linear instability) from the essential spectrum is only possible from the embedded eigenvalues or thresholds, and therefore can not take place beyond the embedded thresholds. We also prove that "in the nonrelativistic limit" $\omega\to m$, the point eigenvalues can only accumulate to $0$ and $\pm 2 m i$.
Comments: 42 pages. The spectral stability of solitary waves in a charge-subcritical NLD in the nonrelativistic limit ($\omega\lesssim m$) will be proved in a forthcoming paper
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