Влияние состава системы BiPO₄-BiVO₄ на фазообразование, морфологию и свойства нанокристаллических композитов, полученных в гидротермальных условиях

Нанокристаллические композиты BiPO₄/BiVO₄ синтезированы в гидротермальных условиях. Определено влияние исходного состава системы на фазовое состояние, размер кристаллитов и морфологию образующихся частиц. На примере разложения метилового фиолетового изучена фотокаталитическая активность нанокомпозита.

1. Malathi A., Madhavan J., Muthupandian Ashokkumar, Prabhakarn Arunachalam. A review on BiVO4 photocatalyst: Activity enhancement methods for solar photocatalytic applications. Applied Catalysis A: General, 2018, 555, P. 47–74.

2. Lin Y.-Y., Chi H.-T., Lin J.-H., Chen F.-H., Chen C.-C., Lu C.-S. Eight crystalline phases of bismuth vanadate by controllable hydrothermal synthesis exhibiting visible-light-driven photocatalytic activity. Molecular Catalysis, 2021, 506, 111547.

3. Abdullah A.H., Ali N.M., Tahir M.I.M. Synthesis of bismuth vanadate as visible-light photocatalyst. Malaysian J. of Analytical Sciences, 2009, 13 (2), P. 151–157.

4. Doli´c S.D., Jovanovi´c D.J., Smits K., Babi´c B., Marinovi´c-Cincovi´c M., Porobi´c S., Drami´canin M.D. A comparative study of photocatalytically active nanocrystalline tetragonal zyrcon-type and monoclinic scheelite-type bismuth vanadate. Ceramics Int., 2018, 44 (15), P. 17953–17961.

5. Nguyen T.D., Hong S.S. Facile solvothermal synthesis of monoclinic-tetragonal heterostructured BiVO4 for photodegradation of rhodamine B. Catalysis Communications, 2020, 136, 105920.

6. Abdi F.F., Savenije T.J., May M.M., Dam B., van de Krol R. The origin of slow carrier transport in BiVO4 thin film photoanodes: a time-resolved microwave conductivity study. The J. of Physical Chemistry Letters, 2013, 4 (16), P. 2752–2829.

7. Jo W. J., Jang J.-W., Kong K., Kang H. J., Kim J. Y., Jun H., Parmar K.P.S., Lee J. S. Phosphate doping into monoclinic BiVO4 for enhanced photoelectrochemical water oxidation activity. Angewandte Chemie, 2012, 124 (13), P. 3201–3205.

8. Ganguli S., Hazra C., Chatti M., Samanta T., Mahalingam V. A highly efficient UV–Vis–NIR active Ln3+-doped BiPO4/BiVO4 nanocomposite for photocatalysis application. Langmuir, 2016, 32 (1), P. 247–253.

9. Shi L., Xue J., Xiao W., Wang P., Long M., Bi Q. Efficient degradation of VOCs using semi-coke activated carbon loaded ternary Z-scheme heterojunction photocatalyst BiVO4–BiPO4-g–C3N4 under visible light irradiation. Physical Chemistry Chemical Physics, 2022, 24 (37), P. 22987– 22997.

10. Yang L., Peng S., Yu L., Zhao M. Microstructural, crystallographic, and luminescent analysis after grinding high-temperature monoclinic bismuth phosphate. J. of Luminescence, 2020, 225, P. 117345.

11. Zhu Y., Ling Q., Liu Y.,Wang H., Zhu Y. Photocatalytic performance of BiPO4 nanorods adjusted via defects. Applied Catalysis B: Environmental, 2016, 187, P. 204–211.

12. Naciri Y., Hsini A., Ajmal Z., Nav´ıo J.A., Bakiz B., Albourine A., Ezahri M., Benlhachemi A. Recent progress on the enhancement of photocatalytic properties of BiPO4 using p-conjugated materials. Advances in Colloid and Interface Science, 2020, 280, 102160.

13. Buyanova E.S., Emelyanova Yu.V., Morozova M.V., Mikhailovskaya Z.A., Kaymieva O.S., Zhukovskiy V.M., Petrova S.A. Crystal structure and conductivity of bismuth-containing complex oxides. Chimica Techno Acta, 2015, 2 (4), P. 306–315.

14. Strobel R., Metz H.J., Pratsinis S.E. Brilliant yellow, transparent pure, and SiO2-coated BiVO4 nanoparticles made in flames. Chemistry of Materials, 2008, 20 (20), P. 6346–6351.

15. Goti´c M., Musi´c S., Ivanda M., ˇSoufek M., Popovi´c S. Synthesis and characterisation of bismuth (III) vanadate. J. of Molecular Structure, 2005, 744–747, P. 535–540.

16. Jiang H.-q., Endo H., Natori H., Nagai M., Kobayashi K. Fabrication and photoactivities of spherical-shaped BiVO4 photocatalysts through solution combustion synthesis method. J. of the European Ceramic Society, 2008, 28 (15), P. 2955–2962.

17. Manjunatha A.S., Pavithra N.S., Marappa S., Prashanth S.A., Nagaraju G., Puttaswamy Green synthesis of flower-like BiVO4 nanoparticles by solution combustion method using lemon (Citrus Limon) juice as a fuel: Photocatalytic and electrochemical study. Chemistry Select, 2018, 3 (47), P. 13456–13463.

18. Kudo A., Omori K., Kato H. A novel aqueous process for preparation of crystal form-controlled and highly crystalline BiVO4 powder from layered vanadates at room temperature and its photocatalytic and photophysical properties. J. of the American Chemical Society. 1999, 121 (49), P. 11459–11467.

19. Neves M.C., Trindade T. Chemical bath deposition of BiVO4. Thin solid films, 2002, 406 (1–2), P. 93–97.

20. Packiaraj R., Devendran P., Bahadur S.A., Nallamuthu N. Structural and electrochemical studies of Scheelite type BiVO4 nanoparticles: synthesis by simple hydrothermal method. J. of Materials Science: Materials in Electronics, 2018, 29 (15), P. 13265–13276.

21. Lin H., Ye H., Chen S., Chen Y. One-pot hydrothermal synthesis of BiPO4/BiVO4 with enhanced visible-light photocatalytic activities for methylene blue degradation. RSC Advances, 2014, 4 (21), P. 10968–10974.

22. Trinh N.D., Hoang H.H., Linh N.X., Vinh N.H., Vu H.T., Nguyen H.T., Vo D.-V.N., Do S.T., Duc L.T. A Facile Synthesis and Properties of Bismuth Vanadate (BiVO4) Photocatalyst by Hydrothermal Method. IOP Conference Series: Materials Science and Engineering, 2019, 542 (1), 012059.

23. Zhang A., Zhang J., Cui N., Tie X., An Y., Li L. Effects of pH on hydrothermal synthesis and characterization of visible-light-driven BiVO4 photocatalyst. J. of Molecular Catalysis A: Chemical, 2009, 304 (1–2), P. 28–32.

24. Samsudin M.F.R., Sufian S., Bashiri R., Mohamed N.M., Ramli R.M. Synergistic effects of pH and calcination temperature on enhancing photodegradation performance of m-BiVO4. J. of the Taiwan Institute of Chemical Engineers, 2017, 81, P. 305–315.

25. Yan Y., Li X., Ni T., Chang K., Li K., Guo Q. In-situ grafting BiVO4 nanocrystals on a BiPO4 surface: Enhanced metronidazole degradation activity under UV and visible light. J. of the Taiwan Institute of Chemical Engineers, 2019, 99, P. 82–92.

26. Yan Y., Ni T., Du J., Li L., Fu S., Li K., Zhou J. Green synthesis of balsam pear-shaped BiVO4/BiPO4 nanocomposite for degradation of organic dye and antibiotic metronidazole. Dalton Transactions, 2018, 47 (17), P. 6089–6101.

27. Halder N.C.,Wagner C.N.J. Separation of Particle Size and Lattice Strain in Integral Breadth Measurements. Acta Crystallographica, 1966, 20 (2), P. 312–313.

28. Seroglazova A.S., Popkov V.I. Synthesis of highly active and visible-light-driven PrFeO3 photocatalyst using solution combustion approach and succinic acid as fuel. Nanosystems: Phys. Chem. Math., 2022, 13 (6), P. 649–654.