Temperature Dependent n-p Transition of 3 Dimensional Dirac Semimetal Na3Bi Thin Film

Abstract

We study the temperature dependence (77 K - 475 K) of the longitudinal resistivity and Hall coefficient of thin films (thickness 20 nm) of three dimensional topological Dirac semimetal Na3Bi grown via molecular beam epitaxy (MBE). The temperature-dependent Hall coefficient is electron-like at low temperature, but transitions to hole-like transport around 200 K. We develop a model of a Dirac band with electron-hole asymmetry in Fermi velocity and mobility (assumed proportional to the square of Fermi velocity) which explains well the magnitude and temperature dependence of the Hall resistivity. We find that the hole mobility is about 7 times larger than the electron mobility. In addition, we find that the electron mobility decreases significantly with increasing temperature, suggesting electron-phonon scattering strongly limits the room temperature mobility.