Effective description of hot QCD medium in strong magnetic field and longitudinal conductivity

Hot QCD medium effects have been studied in the effective quasiparticle description of quark-gluon plasma. This model encodes the collective excitation of gluons and quarks/antiquarks in the thermal medium in terms of effective quarks and gluons having nontrivial energy dispersion relation. The present investigation involves the extension of the effective quasiparticle model in strong magnetic field limit. Realizing hot QCD medium in the strong magnetic field as an effective grand canonical system in terms of the modified quark, antiquark, and gluonic degrees of freedom, the thermodynamics has been studied. Further, the Debye mass in hot QCD medium has to be sensitive to the magnetic field, and subsequently the same has been observed for the effective hot QCD coupling. As an implication, electrical conductivity (longitudinal) has been studied within an effective kinetic theory description of hot QCD in the presence of the strong magnetic field. The hot QCD equation of state dependence entering through the effective coupling and quasiparton distribution function is found to have a significant impact on the longitudinal electrical conductivity in the strong magnetic field background.