Mass splitting and spin alignment for φ mesons in a magnetic field in NJL model

Abstract

Based on the Nambu-Jona-Lasinio (NJL) model, we develop a framework for calculating the spin alignment of vector mesons and applied it to study φ mesons in a magnetic field. We calculate mass spectra for φ mesons and observe mass splitting between the longitudinally polarized state and transversely polarized states. The φ meson in a thermal equilibrium system is preferred to occupy the state with spin λ=0 than those with spin λ=1, because the former state has a smaller energy. As a consequence, we conclude that the spin alignment will be larger than 1/3 if one measures along the direction of the magnetic field, which is qualitatively consistent with the recent STAR data. Around the critical temperature TC=150 MeV, the positive deviation from 1/3 is proportional to the square of the magnetic field strength, which agrees with the result from the non-relativistic coalescence model. Including the anomalous magnetic moments for quarks will modify the dynamical masses of quarks and thus affect the mass spectra and spin alignment of φ mesons. The discussion of spin alignment in the NJL model may help us better understand the formation of hadron's spin structure during the chiral phase transition.