Effects of imaginary and real rotations on QCD matters

Abstract

Inspired from perturbative calculations, this work introduces imaginary ( I) and real () rotation effects to the pure SU(3) gauge potentials simply through variable transformations: The empirical Polyakov loop (PL) potentials can be rewritten as functions of the imaginary chemical potentials of gluons and ghosts (q ij), and the transformations are taken as q ij→ q ij I/T and q ij→ q ij i\,/T, respectively. For the PL potential of Fukushima (V1), a smaller imaginary rotation I tends to suppress PL at all temperature and the deconfinement transition keeps of first order. However, for the PL potential of Munich group (V2), I tends to enhance PL at low temperature T, consistent with lattice simulations; but suppress PL at high T, consistent with perturbative calculations. Moreover, the deconfinement alters from first order to crossover with increasing I as is expected from lattice simulations. On the other hand, the real rotation tends to enhance PL at relatively low T for both potentials, and the (pseudo-)critical temperature decreases with as expected. Therefore, we find that analytic continuation of the phase diagram from imaginary to real rotation is not necessarily valid in the non-perturbative region. Finally, we apply the more successful PL potential V2 to the Polyakov--Nambu-Jona-Lasinio (PNJL) model and discover that I tends to break chiral symmetry while tends to restore it. Especially, the modified model is even able to qualitatively explain the lattice result that a larger T would catalyze chiral symmetry breaking for a large I.

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