Ultrafast response of spontaneous photovoltaic effect in 3R-MoS2-based heterostructures

Rhombohedrally stacked MoS2 has been shown to exhibit spontaneous polarization down to the bilayer limit and can sustain a strong depolarization field when sandwiched between graphene. Such a field gives rise to a spontaneous photovoltaic effect without needing any p-n junction. In this work, we show that the photovoltaic effect has an external quantum efficiency of 10% for devices with only two atomic layers of MoS2 at low tem-peratures, and identify a picosecond-fast photocurrent response, which translates to an intrinsic device band-width at similar to 100-GHz level. To this end, we have developed a nondegenerate pump-probe photocurrent spectroscopy technique to deconvolute the thermal and charge-transfer processes, thus successfully revealing the multicomponent nature of the photocurrent dynamics. The fast component approaches the limit of the charge-transfer speed at the graphene-MoS2 interface. The remarkable efficiency and ultrafast photoresponse in the graphene-3R-MoS2 devices support the use of ferroelectric van der Waals materials for future high-per-formance optoelectronic applications.

Automated summary

By utilizing nondegenerate pump-probe photocurrent spectroscopy technique, the photovoltaic effect of graphene-3R-MoS2 devices was investigated, revealing an external quantum efficiency of 10% and a picosecond-fast photocurrent response speed for devices with only two atomic layers of MoS2 at low temperatures. The study uncovered the multi-component nature of the photocurrent dynamics.