A giant intrinsic photovoltaic effect in atomically thin ReS2

Abstract

The photovoltaic (PV) effect in non-centrosymmetric materials consisting of a single component under homogeneous illumination can exceed the fundamental Shockley–Queisser limit compared to the traditional p–n junctions. Two-dimensional (2D) materials with a reduced dimensionality and smaller bandgap were predicated to be better candidates for the PV effect with high efficiency exceeding that of traditional ferroelectric perovskite oxides. Here, we report the giant intrinsic PV effect in atomically thin rhenium disulfide (ReS₂) with centrosymmetry breaking. In graphene/ReS₂/graphene sandwich structures, significant short-circuit currents (I_sc) were observed with illumination over the visible spectral range, presenting the highest responsivity (110 mA W⁻¹) and external quantum efficiency (25.7%) among those reported PV effects in 2D materials. This giant PV effect could be ascribed to the spontaneous-polarization induced depolarization field in even-number-layered ReS₂ flakes benefiting from the distorted 1T lattice structure. Our results provide a new potential candidate material for the development of novel high-efficiency, miniaturized and easily integrated photodetectors and solar cells.