Abstract
The one loop self energy of the neutral $\rho$ meson is obtained for the effective $\rho\pi\pi$ and $\rho NN$ interaction at finite temperature and density in the presence of a constant background magnetic field of arbitrary strength. In our approach, the eB-dependent vacuum part of the self energy is extracted by means of dimensional regularization where the ultraviolet divergences corresponding to the pure vacuum self energy manifest as the pole singularities of gamma as well as Hurwitz zeta functions. This improved regularization procedure consistently reproduces the expected results in the vanishing magnetic field limit and can be used quite generally in other self energy calculations dealing with arbitrary magnetic field strength. In presence of the external magnetic field, the general Lorentz structure for the in-medium vector boson self energy is derived which can also be implemented in case of the gauge bosons such as photons and gluons. It has been shown that with vanishing perpendicular momentum of the external particle, essentially two form factors are sufficient to describe the self energy completely. Consequently, two distinct modes are observed in the study of the effective mass, dispersion relations and the spectral function of $\rho^0$ where one of the modes possesses two fold degeneracy. For large baryonic chemical potential, it is observed that the critical magnetic field required to block the $\rho^0\rightarrow\pi^+\pi^-$ decay channel increases significantly with temperature. However, in case of smaller values reaching down to vanishing chemical potential, the critical field follows the opposite trend.
Highlights
In noncentral heavy-ion collisions (HIC) at the LHC, the relative motion of the ions themselves can generate a strong decaying magnetic pulse of the order eB ∼ 15m2π (B ∼ 5 × 1015 T) [1]
Two distinct modes are observed in the study of the effective mass, dispersion relations and the spectral function of ρ0 where one of the modes possesses twofold degeneracy
The spectral properties of the neutral ρ meson are studied at finite temperature and density in a constant external magnetic field using the real time formalism of finite temperature field theory
Summary
In noncentral heavy-ion collisions (HIC) at the LHC, the relative motion of the ions themselves can generate a strong decaying magnetic pulse of the order eB ∼ 15m2π (B ∼ 5 × 1015 T) [1]. The oneloop self-energy of a ρ meson is calculated for the effective ρππ and ρNN interaction with magnetically modified pion and nucleon propagators corresponding to general field strength. In order to calculate the ρ0 self-energy at finite temperature and density, we employ the real time formalism (RTF) of finite temperature field theory where all the two point correlation functions such as the propagator and the selfenergy become 2 × 2 matrices in the thermal space [34,35] They can be put in a diagonal form where the diagonal elements can be obtained from any one component (say the 11-component) of the mentioned 2 × 2 matrix. One of the possible ways to incorporate the effect of external magnetic field is the Schwinger proper time formalism in which the 11-components of charged pion and proton propagators respectively become [36,37]. The presence of Kronecker delta functions in the expressions of Nμπν;nlðqk; kkÞ and Nμp;νnlðqk; kkÞ has eliminated one of the double sums, or in other words, the sum over index l runs from (n − 1) to (n þ 1)
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