Subcycle control of valley-selective excitation via dynamical Franz-Keldysh effect in WSe2 monolayer

Abstract

This study performed first-principles calculations based on the time-dependent density functional theory to control the valley degree of freedom relating to the dynamical Franz-Keldysh effect (DFKE) in a monolayer of transition metal dichalcogenide. By mimicking the attosecond transient absorption spectroscopy, we performed numerical pump-probe experiments to observe DFKE around the K or K' valley in WSe2 monolayer with a linearly-polarized pump field and a circularly-polarized probe pulse. We found that the circularly-polarized probe pulse with a given helicity can selectively observe the transient conductivity modulated by DFKE in each valley. The transient conductivity and excitation probability around each valley oscillate with the pump field frequency . The phases of the oscillation for the K and K' valleys are opposite to each other. Furthermore, the pump-driven DFKE alters the absorption rate of WSe2 monolayer and yields the valley-dependent oscillation of the electron excitation induced by the pump plus probe field. With a simplified two-band model, we identified the oscillation of the off-diagonal conductivity caused by the band asymmetry around the valleys as the physical mechanism responsible for the valley-selective DFKE.