Abstract

The construction of two-dimensional (2D) van der Waals (vdW) heterostructures is an effective strategy to overcome the intrinsic disadvantages of individual 2D materials. Herein, by employing first-principles calculations, the electronic structures and potential applications in the photovoltaic field of the β-In2X3/α-In2X3 (X = S and Se) vdW heterostructures have been systematically unraveled. Interestingly, the band alignments of β-In2S3/α-In2S3, β-In2Se3/α-In2Se3, and β-In2Se3/α-In2S3 heterostructures can be transformed from type-I to type-II by switching the polarization direction of α-In2X3 layers. It is highlighted that the light-harvesting ability of the β-In2X3/α-In2X3 vdW heterostructures is significantly higher than the corresponding monolayers in nearly the entire visible light region. Interestingly, type-II β-In2S3/α-In2Se3↓ heterostructure can achieve the power conversion efficiency of 17.9%, where the α-In2Se3 layer acts as a donor and the β-In2S3 layer displays as the acceptor. The present research not only provides an in-depth understanding that the out-of-plane polarization of α-In2X3 monolayers can efficiently modulate the band edge alignment of the β-In2X3/α-In2X3 vdW heterostructures, but also paves the way for the application of these heterostructures in the field of photovoltaics and optoelectronics.

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