Dilepton production rate in a hot and magnetized quark-gluon plasma

Abstract

The differential multiplicity of dileptons in a hot and magnetized quark-gluon plasma, B dNB/d4xd4q, is derived from first principles. The constant magnetic field B is assumed to be aligned in a fixed spatial direction. It is shown that the anisotropy induced by the B field is mainly reflected in the general structure of photon spectral density function. This is related to the imaginary part of the vacuum polarization tensor, Im[μ], which is derived in a first order perturbative approximation. As expected, the final analytical expression for B includes a trace over the product of a photonic part, Im[μ], and a leptonic part, Lμ. It is shown that B consists of two parts, B\| and B, arising from the components (μ,)=(\|,\|) and (μ,)=(,) of Im[μ] and Lμ. Here, the transverse and longitudinal directions are defined with respect to the direction of the B field. Combining B\| and B, a novel anisotropy factor B is introduced. Using the final analytical expression of B, the possible interplay between the temperature T and the magnetic field strength eB on the ratio B/0 and B is numerically studied. Here, 0 is the Born approximated dilepton multiplicity in the absence of external magnetic fields. It is, in particular, shown that for each fixed T and B, in the vicinity of certain threshold energies, B 0 and B B\|. The latter anisotropy may be interpreted as one of the microscopic sources of the macroscopic anisotropies, reflecting themselves, e.g., in the elliptic asymmetry factor v2 of dileptons.