Spin-Orbit Coupling Effect on the Seebeck Coefficient in Dirac Electron Systems in α-(BETS)2I3

Abstract

The Seebeck coefficient, S=L12/(TL11), which is proportional to a ratio of the thermoelectric conductivity L12 to the electric conductivity L11 with T being temperature is examined for two-dimensional Dirac electrons in the three-quarter filled organic conductor, α-(BETS)2I3, [BETS = BEDT-TSeF = bis(ethylenedithio)tetraselenafulvalene] at ambient pressure.Using a tight-binding model obtained with the first-principles relativistic density-functional theory method [Tsumuraya and Suzumura, Eur. Phys. J. B 94, 17 (2021)], we calculate S in the presence of the impurity and electron--phonon scatterings. We show that Sx < 0 and Sy >0 at high temperatures, where Sx (Sy) denotes S perpendicular (parallel) to the molecular stacking axis. There is a sign change of Sy with increasing T. We find that, at low temperatures the absolute value of S is enhanced by the spin-orbit coupling. The Seebeck coefficient is examined by dividing it into components of the conduction and valence bands; we find that the electron and hole contributions compete with each other. Such T dependence of S is clarified using the spectral conductivity, which determines L12 and L11