Abstract
Constructing van der Waals (vdW) hetero-structure by stacking different two-dimensional (2D) materials has become an effective method for designing new-type and high-quality electronic and optoelectronic nano-devices. In this work, we designed a 2D As/BlueP vdW hetero-structure by stacking monolayer arsenene (As) and monolayer blue phosphorous (BlueP) vertically, which were recently implemented in experiments, and investigated its structural, electronic, and photocatalytic water splitting properties by using the standard first principles calculation method with HSE06 hybrid exchange-correlation functional. Numerical results show that the As/BlueP vdW hetero-structure is structural robust, even at room temperature. It presents semi-conducting behavior, and the conduction band minimum (CBM) and the valence band maximum (VBM) are dominated by BlueP and As, respectively. The typical type-II band alignment predicts the potential application of the hetero-structure in highly efficient optoelectronics and solar energy conversion. Moreover, the CBM and the VBM straddle the redox potentials of water in acid environment, predicting the possibility of the As/BlueP hetero-structure as a 2D photocatalyst for water splitting. When an in-plane strain is applied, the band edges and, further, the optoelectronic properties of the hetero-structure can be effectively tuned. Especially, when tensile strain is equal to 4.5%, the optical absorption spectrum is effectively broadened in a visible light region, which will largely improve its photocatalytic efficiency, although the pH value of the solution range reduction. This work provides theoretical evidence that the As/BlueP hetero-structure has potential application as a 2D photocatalyst in water splitting.
Highlights
With the rapid growth of society development and increasing population, the energy requirements will absolutely increase
When sunlight with energy larger than the band gap irradiates on the 2D semiconducting materials, electrons are excited from the valence band to the conduction band to form electron-hole pairs, and hydrogen and oxygen are eventually produced by catalysis on the surface of the material
When compared to the traditional bulk optoelectronic materials, 2D semiconducting materials possess several advantages of adjustable band gap by strain engineer, short charge transfer distance, and huge surface to volume ratio, which will greatly broaden the range of absorption spectra, accelerate catalytic process, and enhance the efficiency of optical absorption [15,16,17,18]
Summary
With the rapid growth of society development and increasing population, the energy requirements will absolutely increase. Exploring the photocatalytic applications of 2D semiconducting materials, especially in water splitting, has become a hot research area, and lots of theoretical and experimental works have been carried out in order to explore the photocatalytic mechanism and detect new 2D materials [10,11,12,13,14]. When sunlight with energy larger than the band gap irradiates on the 2D semiconducting materials, electrons are excited from the valence band to the conduction band to form electron-hole pairs, and hydrogen and oxygen are eventually produced by catalysis on the surface of the material. The finite thickness of 2D material is a double-edged sword, because most of the photo-generated electrons and holes are scattered among the same surface, which enhances electron-hole recombination probability and restricts the efficiency of redox reaction to produce H2 and O2 [19]
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