Interaction-induced magnetoconductivity, magnetoresistivity, and the Hall effect in massive-massless fermion mixtures

The presence of two types of holes, namely the Dirac holes and the heavy holes, in a two-dimensional sample exposed to a weak external permanent magnetic field leads to the emergence of the temperature and magnetic field-dependent contribution to the resistivity due to their interactions. Taking a HgTe-based two-dimensional semimetal as a testbed, we develop a theoretical model describing the role of interactions between the degenerate massive and Dirac particles for the resistivity in the presence of a classical magnetic field. If only the Dirac holes are present in the system, the magnetoconductivity acquires a finite interaction-induced contribution which would be vanishing for the parabolic spectrum. It demonstrates $T^4 \ln(1/T)$ behavior at low temperatures for screened Coulomb interhole interaction potential, asymptotically reaching $T^2$ with increasing temperature. However, the magnetoresistivity and the Hall effect are not affected by the Dirac holes interparticle correlations. Instead, the presence of two types of holes provides a finite contribution to the magnetoconductivity, magnetoresistivity, and the classical Hall effect resistivity. The temperature behavior of the magnetoconductivity here is $T^2$ in the case of the short-range constant interparticle interaciton potential and $T^2 \ln(1/T)$ for the bare unscreened Coulomb interaction.