DENSITY FUNCTIONAL THEORY APPROACH IN INVESTIGATING STRUCTURAL AND ELECTRONIC PROPERTIES OF BISMUTH-BASED PHOTOCATALYSTS

Authors

  • Nguyen Huyen Nhung Student of the Faculty of Physics, Hanoi National University of Education, Hanoi city, Vietnam
  • Tran Phan Thuy Linh Faculty of Physics, Hanoi National University of Education, Hanoi city, Vietnam

DOI:

https://doi.org/10.18173/2354-1059.2025-0055

Keywords:

DFT, Bismuth tungstate, Bismuth molybdate, photocatalyst, band gap

Abstract

Utilizing Density Functional Theory (DFT) as the computational method, we aimed to gain insights into the structural and electronic characteristics of Bi-based photocatalysts, particularly bismuth tungstate and bismuth molybdate. Both materials exhibit an orthorhombic structure and belong to the space group Pca21 under certain conditions. The exchange-correlation functional used throughout the study was the Perdew-Burke-Ernzerhof (PBE) functional within the generalized gradient approximation (GGA), enabling detailed analyses of their crystal structure, electronic band structure, density of states, and charge density. The electronic properties of both photocatalysts exhibit similar features as expected from the similarities in crystal structure. Notably, bismuth molybdate has a narrower band gap than bismuth tungstate, attributed to the atomic size difference between molybdenum and tungsten. The results confirm their semiconductor nature, highlighting their potential for sustainable-energy photocatalytic applications.

References

[1] Ameta R & Ameta SC, (2016). Photocatalysis: Principles and Applications (1st ed.). CRC Press, p. 1-5.

[2] Pan Q, Wu Y, Su X, Yin Y, Shi S, Oderinde O, Yui G, Zhang C & Zhang Y, (2023). A review on the recent development of bismuth-based catalysts for CO₂ photoreduction. Journal of Molecular Structure, 1294(1), 136404.

[3] Zhang L, Li Y, Li Q, Fan J, Carabineiro S A C & Lv K, (2021). Recent advances on Bismuth-based photocatalysts: Strategies and mechanisms. Chemical Engineering Journal, 419, 129484.

[4] Elaouni A, El Ouardi M, BaQais A, Arab M, Saadi M & Ait Ahsaine H, (2023). Bismuth tungstate Bi₂WO₆: A review on structural, photophysical, and photocatalytic properties. RSC Advances, 13, 17476-17494.

[5] Ewald PP (Ed.), (1962). Fifty years of X-ray diffraction. International Union of Crystallography.

[6] Le MT, (2018). Bismuth molybdate-based catalysts for selective oxidation of hydrocarbons. IntechOpen. DOI: 10.5772/intechopen.75105.

[7] Materials Project, (2020). mp-2 4 0: Bi₂WO₆ (orthorhombic, Pca2₁, 2 ). https://legacy.materialsproject.org/materials/mp-23480.

[8] Ahmad H, Rauf A, Ahmad A, Ata Ulhaq & Muhammad S, (2021). First-principles study on the electronic and optical properties of Bi₂WO₆. RSC Advances, 11(51), 32330-32338.

[9] Zeng T, Yu X, Hui S, Zhou Z & Dong X, (2015). Structural and electrical properties of Bi₂WO₆ piezoceramics prepared by solid state reaction method. Materials Research Bulletin, 68, 271-275.

[10] Knight KS, (1992), Mineralogical Magazine, 56, 399-409.

[11] Phuruangrat A, Putdum S, Dumrongrojthanath P, Thongtem S & Thongtem T, (2015). Hydrothermal synthesis of Bi₂MoO₆ visible-light-driven photocatalyst. Journal of Nanomaterials, 1-6. http://dx.doi.org/10.1155/2015/135735.

[12] Autes G, (2025). Bi₂MoO₆ ICSD 37251. https://www.materialscloud.org.

[13] SpringerMaterials, (2024). Bi₂MoO₆ (MoBi₂O₆ rt) Crystal Structure. https://materials.springer.com/isp/crystallographic/docs/sd_0306723.

[14] Chen P, Du T, Jia H, Zhou L, Yue Q, Wang H & Wang Y, (2022). A novel Bi₂WO₆/Si heterostructure photocatalyst with a Fermi level shift in the valence band realizes efficient reduction of CO₂ under visible light. Applied Surface Science, 585, 152665.

[15] Hossain Q S, Mahi T A, Nishat S S, Ahmed S, Sultana M, Khan M N I, Das H N, Bashar M S, Chowdhury F, Akhtar U S, Jahan S, Hossain K S & Ahmed I (2023). First-Principles Calculations on Electronic, Optical, and Phonon Properties of γ-Bi₂MoO₆. RSC Advances, 9(34), 36314-36325.

[16] Liu X, Gu S, Zhao Y, Zhou G & Li W, (2020). BiVO4, Bi₂WO₆, and Bi₂MoO₆ photocatalysis: A brief review. Journal of Materials Science & Technology, 56, 45-68.

[17] Tian J, Sang Y, Yu G, Jiang H, Mu X, & Liu H, (2013). A Bi₂WO₆-Based Hybrid Photocatalyst with Broad Spectrum Photocatalytic Properties under UV, Visible, and Near-Infrared Irradiation. Advanced Materials, 25, 5075.

[18] Jing T, Dai Y, Wei W, Ma X, Huang B, (2014). Near-Infrared Photocatalytic Activity Induced by Intrinsic Defects in Bi₂MO₆ (M = W, Mo). Physical Chemistry Chemical Physics, 16, 18596-1860.

[19] Zhang B, Liu G, Shi H, Wu Q, Xue S, Shao T, Zhang F & Liu X, (2023). Density functional theory study of electronic structure and optical properties of Ln³⁺-doped γ-Bi₂MoO₆ (Ln = Gd, Ho, Yb). Crystals, 13(1158).

[20] Guo C, Xu J, Wang S, Li L, Zhang Y & Li X, (2012). Facile synthesis and photocatalytic application of hierarchical mesoporous Bi₂MoO₆ nanosheet-based microspheres. CrystEngComm, 14(10), 3602.

[21] Umapathy V, Manikandan A, Arul Antony S, Ramu P & Neeraja P, (2015). Structure, morphology, and opto-magnetic properties of Bi₂MoO₆ nano-photocatalyst synthesized by the sol-gel method. Transactions of Nonferrous Metals Society of China, 25(10), 3271-3278.

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Published

30-12-2025

Issue

Volume 70, Issue 4, 2025: Natural Sciences

Section

Articles

How to Cite

Huyen Nhung, N., & Phan Thuy Linh, T. (2025). DENSITY FUNCTIONAL THEORY APPROACH IN INVESTIGATING STRUCTURAL AND ELECTRONIC PROPERTIES OF BISMUTH-BASED PHOTOCATALYSTS. Journal of Science Natural Science, 70(4), 68-77. https://doi.org/10.18173/2354-1059.2025-0055