Transport Signatures of Fermi Surface Topology Change in BiTeI

Abstract

We report a quantum magnetotransport signature of a change in Fermi surface topology in the Rashba semiconductor BiTeI with systematic tuning of the Fermi level EF. Beyond the quantum limit, we observe a marked increase/decrease in electrical resistivity when EF is above/below the Dirac node that we show originates from the Fermi surface topology. This effect represents a measurement of the electron distribution on the low-index (n=0,-1) Landau levels and is uniquely enabled by the finite bulk kz dispersion along the c-axis and strong Rashba spin-orbit coupling strength of the system. The Dirac node is independently identified by Shubnikov-de Haas oscillations as a vanishing Fermi surface cross section at kz=0. Additionally we find that the violation of Kohler's rule allows a distinct insight into the temperature evolution of the observed quantum magnetoresistance effects.