Dual properties of dense quark matter with color superconductivity phenomenon (2310.08211v1)

Abstract: In this paper the massless NJL model extended by the diquark interaction channel is considered. We study its phase structure at zero temperature and in the presence of baryon $\mu_B$, isospin $\mu_I$, chiral $\mu_{5}$ and chiral isospin $\mu_{I5}$ chemical potentials in the mean-field approximation. It is shown that the model thermodynamic potential, which depends on three order parameters, $M$, $\pi_1$ and $\Delta$ (where $M$, $\pi_1$, and $\Delta$ -- are, respectively, chiral, charged pion and diquark condensates of the model), is symmetric with respect to the (dual) transformation when $M\leftrightarrow\pi_1$ and simultaneously $\mu_I\leftrightarrow\mu_{I5}$. As a result, on the mean-field phase portrait of the model the chiral symmetry breaking (CSB) and charged pion condensation (PC) phases turn out to be dually conjugate with each other, which greatly simplifies the study of the phase portrait of the model. In particular, the duality between CSB and charged PC phases means that in the $(\mu_I,\mu_{I5})$-phase portrait these phases are mirror-symmetrical with respect to the line $\mu_I=\mu_{I5}$, which at the same time is the symmetry axis of the color superconducting (CSC) phase. Moreover, it follows from our analysis that chiral $\mu_5$ chemical potential promotes the formation of CSC phase in dense quark matter. And together with $\mu_{I5}$ it can generates the charged PC phase even at $\mu_I=0$.