Abstract

The electrical and Hall conductivities in a uniform magnetic field are evaluated for an interacting pion gas using the kinetic theory approach within the ambit of relaxation time approximation. The in-medium cross sections vis-\`a-vis the relaxation time for $\ensuremath{\pi}\ensuremath{\pi}$ scattering are obtained using a one-loop modified thermal propagator for the exchanged $\ensuremath{\rho}$ and $\ensuremath{\sigma}$ mesons using thermal field theoretic techniques. For higher values of the magnetic field, a monotonic increase of the electrical conductivity with the temperature is observed. However, for a given temperature, the conductivity is found to decrease steadily with magnetic field. The Hall conductivity, at lower values of the magnetic field, is found to decrease with the temperature more rapidly than the electrical conductivity, whereas at higher values of the magnetic field, a linear increase is seen. Use of the in-medium scattering cross section is found to produce a significant effect on the temperature dependence of both electrical and Hall conductivities compared to the case where the vacuum cross section is used.