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Volume 42 Issue 9
Sep.  2024
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Article Contents
WEN Hao, JIN Yang, JING Yilun, ZHAO Ling, ZHOU Jiti. RESEARCH PROGRESS ON PHOTOCATALYTIC DEGRADATION OF ORGANIC POLLUTANTS IN WATER BY BISMUTH VANADATE HETEROJUNCTIONS[J]. ENVIRONMENTAL ENGINEERING , 2024, 42(9): 132-147. doi: 10.13205/j.hjgc.202409013
Citation: WEN Hao, JIN Yang, JING Yilun, ZHAO Ling, ZHOU Jiti. RESEARCH PROGRESS ON PHOTOCATALYTIC DEGRADATION OF ORGANIC POLLUTANTS IN WATER BY BISMUTH VANADATE HETEROJUNCTIONS[J]. ENVIRONMENTAL ENGINEERING , 2024, 42(9): 132-147. doi: 10.13205/j.hjgc.202409013

RESEARCH PROGRESS ON PHOTOCATALYTIC DEGRADATION OF ORGANIC POLLUTANTS IN WATER BY BISMUTH VANADATE HETEROJUNCTIONS

doi: 10.13205/j.hjgc.202409013
  • Received Date: 2024-07-26
    Available Online: 2024-12-02
  • Globally, the major concern related to the environment which human beings need to solve urgently in the 21st century is water environment pollution. As an emerging wastewater treatment technology, photocatalytic technology has the advantages of energy saving, environment-friendly, reusability, and no secondary pollution, and it conforms to the development concept of green, circular and low-carbon. Photocatalysis is one of the promising techniques applied over decades for wastewater treatment. BiVO4, as a hot photocatalyst, has received great attention due to its properties like its good response to visible light to make use of 48% of the visibe spectrum of sunlight, excellent chemical and photonic properties, non-toxic and stable, but it has some limitations such as poor photocharge transport ability and fast electron-hole pair recombination speed. In recent years, relevant researchers have combined BiVO4 with other semiconductor materials to form heterojunction photocatalysts, which improves the charge separation ability of single-component BiVO4, and has good prospects in wastewater treatment applications. In this review, the photocatalytic mechanism (TypeⅠ,TypeⅡ,and Z-scheme), heterostructure construction methods (cooperating with metal oxides, metal sulfides, homobismuth-based materials and MOFs), optimization methods of photocatalytic system (interface contact mode, crystal surface and morphology control, element doping, carbon material modification and vacancy engineering), and application process of BiVO4-based heterojunctions in water treatment (photocatalytic membrane technology, load anchoring) are systematically reviewed. In addition, this review summarizes the urgent scientific problems in current research and provides a reference for the development of efficient BiVO4-based heterojunction photocatalytic materials in the future.
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  • [1]
    GAO C, HE H, QIU W, et al. Oxidative stress, endocrine disturbance, and immune interference in humans showed relationships to serum bisphenol concentrations in a dense industrial area[J]. Environmental Science & Technology, 2021, 55(3): 1953-1963.
    [2]
    QIAO H, ZHOU Y, YU F, et al. Effective removal of cationic dyes using carboxylate-functionalized cellulose nanocrystals[J]. Chemosphere, 2015, 141: 297-303.
    [3]
    MA H, BURGER C, HSIAO B S, et al. Nanofibrous microfiltration membrane based on cellulose nanowhiskers[J]. Biomacromolecules, 2012, 13(1): 180-186.
    [4]
    CARMO P, RIBEIRO A M, RODRIGUES A E, et al. Bulk recovery and purification of vinyl chloride/nitrogen mixtures by MT-TPVSA using activated carbon carbotech DGK[J]. Fluid Phase Equilibria, 2022, 562: 113547.
    [5]
    NYIKA J, DINKA M. Activated bamboo charcoal in water treatment: a mini-review[J]. Materials Today: Proceedings, 2022, 56: 1904-1907.
    [6]
    VARJANI S, RAKHOLIYA P, NG H Y, et al. Microbial degradation of dyes: an overview[J]. Bioresource Technology, 2020, 314: 123728.
    [7]
    CAO J, SANGANYADO E, LIU W, et al. Decolorization and detoxification of Direct Blue 2B by indigenous bacterial consortium[J]. Journal of Environmental Management, 2019, 242: 229-237.
    [8]
    MONIZ S J A, SHEVLIN S A, MARTIN D J, et al. Visible-light driven heterojunction photocatalysts for water splitting: a critical review[J]. Energy & Environmental Science, 2015, 8(3): 731-759.
    [9]
    CHEN L, YIN S F, HUANG R, et al. Hollow peanut-like m-BiVO4: facile synthesis and solar-light-induced photocatalytic property[J]. Cryst Eng Comm, 2012, 14(12): 4217.
    [10]
    PHURUANGRAT A, WANNAPOP S, SAKHON T, et al. Characterization and photocatalytic properties of BiVO4 synthesized by combustion method[J]. Journal of Molecular Structure, 2023, 1274: 134420.
    [11]
    CHEN S, HUANG D, XU P, et al. Facet-engineered surface and interface design of monoclinic scheelite bismuth vanadate for enhanced photocatalytic performance[J]. ACS Catalysis, 2020, 10(2): 1024-1059.
    [12]
    MONIZ S J A, SHEVLIN S A, MARTIN D J, et al. Visible-light driven heterojunction photocatalysts for water splitting: a critical review[J]. Energy & Environmental Science, 2015, 8(3): 731-759.
    [13]
    CHEN L, HE J, LIU Y, et al. Recent advances in bismuth-containing photocatalysts with heterojunctions[J]. Chinese Journal of Catalysis, 2016, 37(6): 780-791.
    [14]
    MONFORT O, PLESCH G. Bismuth vanadate-based semiconductor photocatalysts: a short critical review on the efficiency and the mechanism of photodegradation of organic pollutants[J]. Environmental Science and Pollution Research, 2018, 25(20): 19362-19379.
    [15]
    ZHONG X, LI Y, WU H, et al. Recent progress in BiVO4-based heterojunction nanomaterials for photocatalytic applications[J]. Materials Science and Engineering: B, 2023, 289: 116278.
    [16]
    ZHANG L, ZHANG J, YU H, et al. Emerging S-scheme photocatalyst[J]. Advanced Materials, 2022, 34(11): 2107668.
    [17]
    LIU C, ZHOU J, SU J, et al. Turning the unwanted surface bismuth enrichment to favourable BiVO4/BiOCl heterojunction for enhanced photoelectrochemical performance[J]. Applied Catalysis B: Environmental, 2019, 241: 506-513.
    [18]
    XIONG B, WU Y, DU J, et al. Cu3Mo2O9/BiVO4 heterojunction films with integrated thermodynamic and kinetic advantages for solar water oxidation[J]. ACS Sustainable Chemistry & Engineering, 2020, 8(37): 14082-14090.
    [19]
    JIANG Z, WANG T, WANG J, et al. Oxygen vacancy-rich BiVO4 modified with mesoporous MIL-88A(Fe) Z-scheme heterojunction for enhanced photocatalytic formaldehyde degradation[J]. Separation and Purification Technology, 2025, 353: 128581.
    [20]
    HE P, SUN L, KHAN S, et al. Construction of a bifunctional BiVO4 based S-scheme heterojunction for enhancing photothermal-photocatalytic oxygen generation and benzaldehyde production[J]. Fuel, 2024, 370: 131813.
    [21]
    WANG Y, TAN G, REN H, et al. Synthesis of BiVO4 with surface heterojunction for enhancing photocatalytic activity by low temperature aqueous method[J]. Materials Letters, 2018, 229: 308-311.
    [22]
    XIAO X L, ZHAO Y N, LIU T. et al. Flower-like SrTiO3/BiVO4 heterojunction nanocomposite photocatalyst for effective degradation of tetracycline[J]. Russian Journal of Physical Chemistry A, 2022, 96: 3038-3044.
    [23]
    LI R, CHEN H, XIONG J, et al. A mini review on bismuth-based Z-scheme photocatalysts[J]. Materials, 2020, 13(22): 5057.
    [24]
    KUILA A, SARAVANAN P, ROUTU S, et al. Improved charge carrier dynamics through a type Ⅱ staggered Ce MOF/mc BiVO4 n-n heterojunction for enhanced visible light utilisation[J]. Applied Surface Science, 2021, 553: 149556.
    [25]
    KAUSHIK B, RANA P, RAWAT D, et al. Synergic effect of type Ⅱ ZnO/BiVO4 magnetic heterostructures for visible light-driven degradation of bisphenol A and methyl violet[J]. Applied Organometallic Chemistry, 2023, 37(1): e6936.
    [26]
    马英楠, 李希成, 张清雅, 等. 可见光驱动Z型异质结光催化剂处理染料废水的研究进展[J]. 环境化学, 2024, 43(11): 1-15.
    [27]
    BARD A J. Photoelectrochemistry and heterogeneous photo-catalysis at semiconductors[J]. Journal of Photochemistry, 1979, 10(1): 59-75.
    [28]
    LIU X, ZHANG Q, MA D. Advances in 2D/2D Z-scheme heterojunctions for photocatalytic applications[J]. Solar RRL, 2021, 5(2): 2000397.
    [29]
    LIU Y, CHEN J, ZHANG J, et al. (1)Z-scheme BiVO4/Ag/Ag2S composites with enhanced photocatalytic efficiency under visible light[J]. RSC Advances, 2020, 10(51): 30245-30253.
    [30]
    CHEN Y, XIE X, SI Y, et al. Constructing a novel hierarchical β-Ag2MoO4/BiVO4 photocatalyst with Z-scheme heterojunction utilizing Ag as an electron mediator[J]. Applied Surface Science, 2019, 498: 143860.
    [31]
    ZHOU Y, CHEN Z, LI J, et al. Highly efficient Z-scheme photocatalysts of Ag/AgIn5S8 decoration on surfaces with high exposure (040) BiVO4 for enhanced photocatalytic performance[J]. Journal of Physics and Chemistry of Solids, 2022, 171: 111038.
    [32]
    FAN Y, YANG R, ZHU R. Leaf-inspired structural design of artificial leaf BiVO4/InVO4 heterojunction with enhanced photocatalytic activity for pollutant degradation[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2020, 589: 124448.
    [33]
    TANG Q Y, LUO X L, YANG S Y, et al. Novel Z-scheme In2S3/BiVO4 composites with improved visible-light photocatalytic performance and stability for glyphosate degradation[J]. Separation and Purification Technology, 2020, 248: 117039.
    [34]
    SHARMA S K, KUMAR A, SHARMA G, et al. Fe3O4 mediated Z-scheme BiVO4/Cr2V4O13 strongly coupled nano-heterojunction for rapid degradation of fluoxetine under visible light[J]. Materials Letters, 2020, 281: 128650.
    [35]
    XU M, YANG J, SUN C, et al. Facile assembly of BiVO4/protonated g-C3N4/AgI with a novel dual Z-scheme mechanism for visible-light photocatalytic degradation of Rhodamine B[J]. Journal of Materials Science, 2021, 56(2): 1328346.
    [36]
    BAO S, WU Q, CHANG S, et al. Z-scheme CdS-Au-BiVO4 with enhanced photocatalytic activity for organic contaminant decomposition[J]. Catalysis Science & Technology, 2017, 7(1): 124-132.
    [37]
    GAO Y, LIU F, CHI X, et al. A mesoporous nanofibrous BiVO4-Ni/AgVO3 Z-scheme heterojunction photocatalyst with enhanced photocatalytic reduction of Cr6+ and degradation of RhB under visible light[J]. Applied Surface Science, 2022, 603: 154416.
    [38]
    PENG Q, LIU S, MAO Y, et al. Preparation of ZnCo2O4/BiVO4 Z-Scheme heterostructures to enhance photocatalytic performance in organic pollutant and antibiotic removal[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2022, 655: 130165.
    [39]
    FAKHRAVAR S, FARHADIAN M, TANGESTANINEJAD S. Excellent performance of a novel dual Z-scheme Cu2S/Ag2S/BiVO4 heterostructure in metronidazole degradation in batch and continuous systems: immobilization of catalytic particles on α-Al2O3 fiber[J]. Applied Surface Science, 2020, 505: 144599.
    [40]
    SAMSUDIN M F R, MAHMOOD A, SUFIAN S. Enhanced photocatalytic degradation of wastewater over RGO-TiO2/BiVO4 photocatalyst under solar light irradiation[J]. Journal of Molecular Liquids, 2018, 268: 26-36.
    [41]
    LIAQAT M, AHSAN S, IQBAL T, et al. Efficient synthesis and characterization of novel BiVO4/ZnO/graphene composites to study enhanced photocatalytic activity for organic pollutant degradation[J]. Journal of Physics D: Applied Physics, 2024, 57(12): 125301.
    [42]
    XU J, WANG W, WANG J, et al. Controlled fabrication and enhanced photocatalystic performance of BiVO4@CeO2 hollow microspheres for the visible-light-driven degradation of rhodamine B[J]. Applied Surface Science, 2015, 349: 529-537.
    [43]
    FU Q, MENG Y, YAO Y, et al. Construction of facet orientation-supported Z-scheme heterojunction of BiVO4(110)-Fe2O3 and its photocatalytic degradation of tetracycline[J]. Journal of Environmental Chemical Engineering, 2023, 11(5): 111060.
    [44]
    KRISHNAN A, SWARNALAL A, DAS D, et al. A review on transition metal oxides based photocatalysts for degradation of synthetic organic pollutants[J]. Journal of Environmental Sciences, 2024, 139: 389-417.
    [45]
    MA C, LEE J, KIM Y, et al. Rational design of α-Fe2O3 nanocubes supported BiVO4 Z-scheme photocatalyst for photocatalytic degradation of antibiotic under visible light[J]. Journal of Colloid and Interface Science, 2021, 581: 514-522.
    [46]
    ABRISHAMI-Rad A, SADEGHZADEH-Attar A. Fe-doped BiVO4 photocatalyst assisting SnO2 nanorod arrays for efficient visible-light-driven degradation of Basic Red 46[J]. Journal of the Taiwan Institute of Chemical Engineers, 2023, 151: 105110.
    [47]
    ORIMOLADE B O, ZWANE B N, KOIKI B A, et al. Solar photoelectrocatalytic degradation of ciprofloxacin at a FTO/BiVO4/MnO2 anode: kinetics, intermediate products and degradation pathway studies[J]. Journal of Environmental Chemical Engineering, 2020, 8(1): 103607.
    [48]
    PENG Y, CAI J, SHI Y, et al. Thin p-type NiO nanosheet modified peanut-shaped monoclinic BiVO4 for enhanced charge separation and photocatalytic activities[J]. Catalysis Science & Technology, 2022, 12(16): 5162-5170.
    [49]
    LIAQAT M, IQBAL T, ASHFAQ Z, et al. Comparative photocatalytic study of visible light driven BiVO4, Cu2O, and Cu2O/BiVO4 nanocomposite for degradation of antibiotic for wastewater treatment[J]. The Journal of Chemical Physics, 2023, 159(20): 204704.
    [50]
    LI Y, CHEN K X, WANG X, et al. Efficient removal of TBBPA with a Z-scheme BiVO4-(rGO-Cu2O) photocatalyst under sunlight irradiation[J]. Chemosphere, 2022, 308: 136259.
    [51]
    XIONG B, WU Y, DU J, et al. Cu3Mo2O9/BiVO4 Heterojunction films with integrated thermodynamic and kinetic advantages for solar water oxidation[J]. ACS Sustainable Chemistry & Engineering, 2020, 8(37): 14082-14090.
    [52]
    WANG B, QIAN K, YANG W, et al. ZnFe2O4/BiVO4 Z-scheme heterojunction for efficient visible-light photocatalytic degradation of ciprofloxacin[J]. Frontiers of Chemical Science and Engineering, 2023, 17(11): 1728-1740.
    [53]
    GAO Y, LI Y, YANG G, et al. Fe2TiO5 as an efficient co-catalyst to improve the photoelectrochemical water splitting performance of BiVO4[J]. ACS Applied Materials & Interfaces, 2018, 10(46): 39713-39722.
    [54]
    KUMAR P S, BARIKI R, KUMAR N S, et al. Low temperature in situ fabrication of NiFe2O4/tetragonal-BiVO4/Bi2MoO6 ternary heterostructure: a conjugated step-scheme multijunction photocatalyst with synergistic charge migration for antibiotic photodegradation and H2 generation[J]. Journal of Colloid and Interface Science, 2024, 654: 523-538.
    [55]
    DIEU C N T, PHAM H D, PHAM T D, et al. Novel photocatalytic performance of magnetically recoverable MnFe2O4/BiVO4 for polluted antibiotics degradation[J]. Ceramics International, 2021, 47(2): 1686-1692.
    [56]
    李孟蝶, 王祖民, 齐健, 等. 金属氧化物异质结的构建及在光催化CO2还原反应中应用的研究进展[J]. 高等学校化学学报, 2023, 44(10): 1-17.
    [57]
    ZHAO B, SHEN D, ZHANG Z, et al. 2D metallic transition-metal dichalcogenides: structures, synthesis, properties, and applications[J]. Advanced Functional Materials, 2021, 31(48): 2105132.
    [58]
    ZHENG X, ZHANG X, CAI Y, et al. Efficient degradation of bisphenol A with MoS2/BiVO4 hetero-nanoflower as a heterogenous peroxymonosulfate activator under visible-light irradiation[J]. Chemosphere, 2022, 289: 133158.
    [59]
    WANG J, SUN S, ZHOU R, et al. A review: synthesis, modification and photocatalytic applications of ZnIn2S4[J]. Journal of Materials Science & Technology, 2021, 78: 1-19.
    [60]
    WANG S, ZHAO L, GAO L, et al. Fabrication of ternary dual Z-scheme AgI/ZnIn2S4/BiVO4 heterojunction photocatalyst with enhanced photocatalytic degradation of tetracycline under visible light[J]. Arabian Journal of Chemistry, 2022, 15(10): 104159.
    [61]
    MARTINCOVÁ J, OTYEPKA M, LAZAR P. Oxidation of metallic two-dimensional transition metal dichalcogenides: 1T-MoS2 and 1T-TaS2[J]. 2D Materials, 2020, 7(4): 045005.
    [62]
    OPOKU F, GOVENDER K K, VAN SITTERT C G C E, et al. Role of MoS2 and WS2 monolayers on photocatalytic hydrogen production and the pollutant degradation of monoclinic BiVO4: a first-principles study[J]. New Journal of Chemistry, 2017, 41(20): 11701-11713.
    [63]
    PENG L G, WANG H, LIU J, et al. Fabrication of fibrous BiVO4/Bi2S3/MoS2 heterojunction and synergetic enhancement of photocatalytic activity towards pollutant degradation[J]. Journal of Solid State Chemistry, 2021, 299: 122195.
    [64]
    DANG P N, HUY H L, GUO P C, et al. Study of photocatalytic activities of Bi2WO6/BiVO4 nanocomposites[J]. Journal of Sol-Gel Science and Technology, 2017, 83(3): 640-646.
    [65]
    XU Z, QIN C, ZHONG J, et al. In-situ preparation of S-scheme BiOI/BiVO4 heterojunctions with enhanced photocatalytic performance[J]. Solid State Sciences, 2022, 129: 106908.
    [66]
    WU X, ZHOU H, GU S, et al. In situ preparation of novel heterojunction BiOBr/BiVO4 photocatalysts with enhanced visible light photocatalytic activity[J]. RSC Advances, 2015, 5(112): 92769-92777.
    [67]
    YAN Y, NI T, DU J, et al. Green synthesis of balsam pear-shaped BiVO4/BiPO4 nanocomposite for degradation of organic dye and antibiotic metronidazole[J]. Dalton Transactions, 2018, 47(17): 6089-6101.
    [68]
    LI J, LU P, DENG W, et al. Facile synthesis of sheet-like BiVO4/Bi4V2O11 composite for enhanced photocatalytic properties[J]. Materials Chemistry and Physics, 2020, 254: 123489.
    [69]
    HUANG R, XIE Y, YU C, et al. enhanced visible light photocatalytic performance of a novel spindle-like BiVO4/Bi2MoO6 heterostructure with photocarrier relaxation behavior[J]. Transactions of the Indian Institute of Metals, 2022, 75(8): 1989-1997.
    [70]
    HE Z, SHI Y, GAO C, et al. BiOCl/BiVO4 p-n heterojunction with enhanced photocatalytic activity under visible-light irradiation[J]. The Journal of Physical Chemistry C, 2014, 118(1): 389-398.
    [71]
    CHEN F, ZHANG X, TANG Y, et al. Facile and rapid synthesis of a novel spindle-like heterojunction BiVO4 showing enhanced visible-light-driven photoactivity[J]. RSC Advances, 2020, 10(9): 5234-5240.
    [72]
    YU Y, SUN Y, GE B, et al. Synergistic removal of organic pollutants from water by CTF/BiVO4 heterojunction photocatalysts[J]. Environmental Science and Pollution Research, 2022, 30(10): 27570-27582.
    [73]
    GUO R, XING Y, LIU M, et al. Facile synthesis of BiVO4@ZIF-8 composite with heterojunction structure for photocatalytic wastewater treatment[J]. Materials, 2021, 14(23): 7424.
    [74]
    SUN J, WANG C, SHEN T, et al. Engineering the dimensional interface of BiVO4-2D Reduced Graphene Oxide (RGO) nanocomposite for enhanced visible light photocatalytic performance[J]. Nanomaterials, 2019, 9(6): 907.
    [75]
    LIU P, YI J, BAO R, et al. Theory-oriented synthesis of 2D/2D BiVO4/MXene heterojunction for simultaneous removal of Hexavalent Chromium and Methylene Blue[J]. Chem Cat Chem, 2021, 13(13): 3046-3053.
    [76]
    PENG H, XING Z, KONG W, et al. Plasmon Ag/CuInS2/BiVO4 core-shell decahedral S-scheme heterojunction superstructures for robust photocatalytic performance[J]. Fuel, 2023, 346: 128368.
    [77]
    YANG R, ZHU Z, HU C, et al. One-step preparation (3D/2D/2D) BiVO4/FeVO4@rGO heterojunction composite photocatalyst for the removal of tetracycline and hexavalent chromium ions in water[J]. Chemical Engineering Journal, 2020, 390: 124522.
    [78]
    MA C, SEO W C, LEE J, et al. Construction of quantum dots self-decorated BiVO4/reduced graphene hydrogel composite photocatalyst with improved photocatalytic performance for antibiotics degradation[J]. Chemosphere, 2021, 275: 130052.
    [79]
    ANG Z R, YU Q, XU Y J. Toward improving the photocatalytic activity of BiVO4-graphene 2D-2D composites under visible light by the addition of mediator[J]. RSC Advances, 2014, 4(102): 58448-58452.
    [80]
    XUE Y, CHEN Z, WU Z, et al. Hierarchical construction of a new Z-scheme Bi/BiVO4-CdS heterojunction for enhanced visible-light photocatalytic degradation of tetracycline hydrochloride[J]. Separation and Purification Technology, 2021, 275: 119152.
    [81]
    LI Z, JIN C, WANG M, et al. Novel rugby-like g-C3N4/BiVO4 core/shell Z-scheme composites prepared via low-temperature hydrothermal method for enhanced photocatalytic performance[J]. Separation and Purification Technology, 2020, 232: 115937.
    [82]
    AGHAKHANINEJAD S, ZARGARI S, RAHIMI R. Synthesis of pineapple slab like morphology of ternary BiVO4/graphene/porphyrin nanocomposite with enhanced visible light photocatalytic activity[J]. SN Applied Sciences, 2020, 2(4): 625.
    [83]
    WANG Y, YU D, WANG W, et al. Synthesizing Co3O4-BiVO4/g-C3N4 heterojunction composites for superior photocatalytic redox activity[J]. Separation and Purification Technology, 2020, 239: 116562.
    [84]
    LI H, CHEN Y, ZHOU W, et al. Tuning in BiVO4/Bi4V2O10 porous heterophase nanospheres for synergistic photocatalytic degradation of organic pollutants[J]. Applied Surface Science, 2019, 470: 631-638.
    [85]
    CHEN L, FENG X. Synthesis and characterization of V2O5/BiVO4 cake-like microstructures[J]. Journal of the Australian Ceramic Society, 2019, 55(4): 1067-1074.
    [86]
    TSUCHIMOCHI T, TAKAOKI K, NISHIGUCHI K, et al. First-principles investigation on the heterostructure photocatalyst comprising BiVO4 and few-layer black phosphorus[J]. The Journal of Physical Chemistry C, 2021, 125(40): 21840-21850.
    [87]
    KANG J, TANG Y, WANG M, et al. The enhanced peroxymonosulfate-assisted photocatalytic degradation of tetracycline under visible light by g-C3N4/Na-BiVO4 heterojunction catalyst and its mechanism[J]. Journal of Environmental Chemical Engineering, 2021, 9(4): 105524.
    [88]
    WANG M, GUO P, ZHANG Y, et al. Eu doped g-C3N4 nanosheet coated on flower-like BiVO4 powders with enhanced visible light photocatalytic for tetracycline degradation[J]. Applied Surface Science, 2018, 453: 11-22.
    [89]
    SINGH S, SHARMA R, MEHTA B R. Enhanced surface area, high Zn interstitial defects and band gap reduction in N-doped ZnO nanosheets coupled with BiVO4 leads to improved photocatalytic performance[J]. Applied Surface Science, 2017, 411: 321-330.
    [90]
    SONG R, KANG S, YAO L, et al. Construction of an La-BiVO4/O-Doped g-C3N4 heterojunction photocatalyst embedded in electrospinning nanofibers[J]. Langmuir, 2023, 39(19): 6647-6656.
    [91]
    WANG M, YU H, WANG P, et al. Promoted photocatalytic degradation and detoxication performance for norfloxacin on Z-scheme phosphate-doped BiVO4/graphene quantum dots/P-doped g-C3N4[J]. Separation and Purification Technology, 2021, 274: 118692.
    [92]
    WANG Y, LIU S, ZHAO C, et al. Comparison study of BiVO4 heterojunctions photocatalyst with different carbon materials[J]. Research on Chemical Intermediates, 2017, 43(11): 6627-6638.
    [93]
    WEN Y, WANG Z, CAI Y, et al. S-scheme BiVO4/CQDs/β-FeOOH photocatalyst for efficient degradation of ofloxacin: reactive oxygen species transformation mechanism insight[J]. Chemosphere, 2022, 295: 133784.
    [94]
    ZHU Z, HAN Q, YU D, et al. A novel p-n heterojunction of BiVO4/TiO2/GO composite for enhanced visible-light-driven photocatalytic activity[J]. Materials Letters, 2017, 209: 379-383.
    [95]
    WANG T, LI C, JI J, et al. Reduced graphene oxide (rGO)/BiVO4 composites with maximized interfacial coupling for visible light photocatalysis[J]. ACS Sustainable Chemistry & Engineering, 2014, 2(10): 2253-2258.
    [96]
    MORAL-RODRÍGUEZ A I, QUINTANA M, LEYVA-RAMOS R, et al. Novel and green synthesis of BiVO4 and GO/BiVO4 photocatalysts for efficient dyes degradation under blue LED illumination[J]. Ceramics International, 2022, 48(1): 1264-1276.
    [97]
    LI Y, ZHONG J, LI J, et al. Enhanced visible light-driven photocatalytic destruction of decontaminants over Bi2O3/BiVO4 heterojunctions with rich oxygen vacancies[J]. Chemical Physics Letters, 2022, 801: 139722.
    [98]
    SHI H, LI C, ZHENG R, et al. Synergistic effect of oxygen vacancies and built-in electric field in GdCrO3/BiVO4 composites for boosted photocatalytic reduction of nitrate in water[J]. Journal of Cleaner Production, 2023, 407: 137088.
    [99]
    SISAY E J, VERÉB G, PAP Z, et al. Visible-light-driven photocatalytic PVDF-TiO2/CNT/BiVO4 hybrid nanocomposite ultrafiltration membrane for dairy wastewater treatment[J]. Chemosphere, 2022, 307: 135589.
    [100]
    WANG X, YE K H, YU X, et al. Polyaniline as a new type of hole-transporting material to significantly increase the solar water splitting performance of BiVO4 photoanodes[J]. Journal of Power Sources, 2018, 391: 34-40.
    [101]
    LI X, CHEN Y, TAO Y, et al. Challenges of photocatalysis and their coping strategies[J]. Chem Catalysis, 2022, 2(6): 1315-1345.
    [102]
    ZHANG J, WU H, SHI L, et al. Photocatalysis coupling with membrane technology for sustainable and continuous purification of wastewater[J]. Separation and Purification Technology, 2024, 329: 125225.
    [103]
    YUAN Y, HE J, DONG W, et al. Nanoarchitectonics of CuO/α-Fe2O3/BiVO4 photocatalysts with double heterojunctions on PVDF membranes: investigating sulfadiazine removal and antifouling properties[J]. Chemical Engineering Journal, 2024, 487: 150445.
    [104]
    SISAY E J, VERÉB G, PAP Z, et al. Visible-light-driven photocatalytic PVDF-TiO2/CNT/BiVO4 hybrid nanocomposite ultrafiltration membrane for dairy wastewater treatment[J]. Chemosphere, 2022, 307: 135589.
    [105]
    YANG J, LIU D, SONG X, et al. Recent progress of cellulose-based hydrogel photocatalysts and their applications[J]. Gels, 2022, 8(5): 270.
    [106]
    LIMPICHAIPANIT A, TUNKASIRI T, NGAMJARUROJANA A. Optical and photocatalytic properties of bismuth vanadate doped bismuth silicate glasses[J]. Optik, 2019, 182: 496-499.
    [107]
    AHMED T, ZHANG H L, XU H B, et al. m-BiVO4 hollow spheres coated on carbon fiber with superior reusability as photocatalyst[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2017, 531: 213-220.
    [108]
    RAHIMI B, JAFARI N, ABDOLAHNEJAD A, et al. Application of efficient photocatalytic process using a novel BiVO4/TiO2-NaY zeolite composite for removal of acid orange 10 dye in aqueous solutions: modeling by response surface methodology (RSM)[J]. Journal of Environmental Chemical Engineering, 2019, 7(4): 103253.
    [109]
    YU B, REDDY N, LIU B, et al. Sequential assembly of PEDOT/BiVO4/FeOOH onto cotton fabrics for photocatalytic degradation of reactive dyes[J]. Cellulose, 2021, 28(17): 11051-11066.
    [110]
    BENDAHOU A, HAJLANE A, DUFRESNE A, et al. Esterification and amidation for grafting long aliphatic chains on to cellulose nanocrystals: a comparative study[J]. Research on Chemical Intermediates, 2015, 41(7): 4293-4310.
    [111]
    STÖHR M, SADHUKHAN M, AL-HAMDANI Y S, et al. Coulomb interactions between dipolar quantum fluctuations in van der Waals bound molecules and materials[J]. Nature Communications, 2021, 12(1): 137.
    [112]
    WANG T, LIU X, MA C, et al. In situ construction of BiVO4(-) cellulose fibers@CDs(-) polyvinyl alcohol composites for tetracycline photocatalytic degradation[J]. Science China Technological Sciences, 2021, 64(3): 548-558.
    [113]
    MOHAMED A M, ABDELWAHAB S M, ELSAWY N M, et al. E-beam irradiation-induced synthesis of hydroxyethyl cellulose/(Cu2O-rGO)/ BiVO4-based nanocomposite for photocatalytic remediation of wastewater under visible light[J]. International Journal of Biological Macromolecules, 2024, 258: 128681.
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