Non-linear flow of two-dimensional viscous electron fluid in moderate magnetic fields

Abstract: In two-dimensional (2D) electron systems, the inter-particle interaction can lead to the formation of a viscous electron fluid and realization of the hydrodynamic regime of electron transport. Here a nonlinear model of the electron hydrodynamic transport is constructed based on the accounting of pair correlations in the electron dynamics. When describing these systems within the framework of classical kinetics, such correlations represent subsequent ``extended'' collisions of the same electrons temporarily joined into pairs. We study their influence on stationary magnetotransport for large-amplitude fluid flows in long samples. Current profiles in the nonlinear regime and the corresponding differential magnetoresistance are calculated. Pair correlations lead to a characteristic nonmonotonic dependence of the differential resistance on magnetic field. We compare our results with experimental data on magnetoresistance of 2D electrons in high-purity GaAs quantum wells; our model can be responsible for a part of the observed features of the differential magnetoresistance.