S-type Heterojunction of MOS2/g-C3N4: Construction and Photocatalysis

doi:10.15541/jim20230096

Abstract

Abstract:

Preparation of highly efficient and stable photocatalysts is crucial for the development of photocatalysis technology. In this study, the method of ultrasonic-assisted deposition and low-temperature calcination was used to prepare MoS₂/g-C₃N₄ S-type heterojunction photocatalyst (MGCD). Effects of the phase structure, micro-morphology, optical absorption performance, X-ray photoelectron spectroscopy, electrochemical AC impedance, and photocurrent of the materials on the photocatalytic activity were comprehensively investigated. The results show that, after ultrasonic-assisted deposition-calcination treatment, MoS₂microspheres were broken, dispersed and combined on the surface of g-C₃N₄ nanosheets, and formed a kind of heterojunction. Under visible light, the degradation rate of 5%MGCD (with 5% MoS₂ addition) for Rhodamine B (RhB) reached 99% in 20 min, and still reach 95.2% when the sample was reused for 5 times, showing good photocatalytic performance and stability. Further analysis from the point of view of the formation of built-in electric field shows that the band bending caused by built-in electric field, coupled with MoS₂ and g-C₃N₄ in heterojunction, can effectively guide the directional migration of carriers, which can efficiently promote the separation of photogenerated carriers, thus improving the efficiency of photocatalytic reaction. Free radical capture experiment of heterojunction photocatalyst reveals that O₂^- and ·OH are the main active species in the catalytic degradation of RhB, followed by H⁺.

Key words: g-C₃N₄, MoS₂, S-type heterojunction, stability, photocatalytic mechanism

CLC Number:

O649

MA Rundong, GUO Xiong, SHI Kaixuan, AN Shengli, WANG Ruifen, GUO Ruihua. S-type Heterojunction of MOS₂/g-C₃N₄: Construction and Photocatalysis[J]. Journal of Inorganic Materials, 2023, 38(10): 1176-1182.

Figures/Tables 6

Fig. 1 XRD patterns of different samples (a), XRD patterns of MoS2 samples before and after calcination (b), and FT-IR spectra of samples (c)

Fig. 2 FE-SEM images of g-C3N4 (a), MoS2 (b) and FE-SEM images (c, d), HR-TEM images (e, f),element mapping (g) and C (h), N (i), S (j), Mo (k) mapping of 5%MGCD

Fig. 3 UV-Vis (a) spectra, Tauc curves (b), PL spectra (c), instantaneous meter photocurrents (d), and EIS (e) patterns of samples Colorful figures are available on website

Fig. 4 Degradation rate of different photocatalyst samples (a), cyclic degradation rate of 5%MGCD with time (b), XRD patterns of 5%MGCD before and after circulation experiment (c), and histogram of free radical trapping experiment (d)

Fig. 5 Energy bands diagram of heterojunction (a), construction of heterojunction of sample and bending of Fermi energy level (b), and diagram of energy band bending caused by built-in electric field (c)

Fig. 6 Photocatalytic mechanism diagram of sample

References 31

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S-type Heterojunction of MOS₂/g-C₃N₄: Construction and Photocatalysis

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