Spontaneous non-Hermiticity in the (2+1)-dimensional Gross-Neveu model

Abstract

Using a nonperturbative approach based on the Cornwall-Jackiw-Tomboulis effective action (S) for composite operators (S is the full fermion propagator), the phase structure of the simplest massless (2 + 1)-dimensional Gross-Neveu model is investigated. We have calculated (S) and its stationary (or Dyson-Schwinger) equation in the first order of the bare coupling constant G and have shown that there exist a well-defined dependence of G G() on the cutoff parameter , such that the Dyson-Schwinger equation is renormalized. It has three different solutions for fermion propagator S corresponding to possible dynamical appearance of three different mass terms in the model. One is a Hermitian, but two others are non-Hermitian and even or odd. It means that two phases with spontaneous non-Hermiticity can be emerged in the system. Moreover, mass spectrum of quasiparticles is real in these non-Hermitian and even/odd phases.

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