Solitary waves in a Two Parameter Family of Generalized Nonlinear Dirac Equations in 1+1 Dimensions
Abstract
We obtain exact solutions of the nonlinear Dirac equation in 1+1 dimension of the form (x,t) = (x) e-i ω t where the nonlinear interactions are a combination of vector-vector (V-V) and scalar-scalar (S-S) interactions with the interaction Lagrangian given by LI= g2(+1)( )+1 -g2p(+1)[ γμ γμ ](+1)/2. This generalizes the model of ABS (N.V. Alexeeva, I.V. Barashenkov and A. Saxena, Annals Phys. 403, 198, (2019)) by having the arbitrary nonlinearity parameter >0 and by replacing the coefficient of the V-V interaction by the arbitrary positive parameter p>1 which alters the relative weights of the vector-vector and the scalar-scalar interactions. We show that the solitary wave solutions exist in the entire allowed (,p) plane for ω/m > 1/p1/(+1) , for frequency ω and mass m. These solutions have the property that their energy divided by their charge is independent of the coupling constant g. As ω increases, there is a transition from the double humped to the single humped solitons. We discuss the regions of stability of these solutions as a function of ω,p, using the Vakhitov-Kolokolov criterion. Finally we discuss the non-relativistic reduction of the 2-parameter family of generalized ABS models to a modified nonlinear Schr\"odinger equation (NLSE) and discuss the stability of the solitary waves in the domain of validity of the modified NLSE.
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