[1] [1] LIN B, CHATURVEDI A, DI J, et al. Ferroelectric-field accelerated charge transfer in 2D CuInP2S6 heterostructure for enhanced photocatalytic H2 evolution[J]. Nano Energy, 2020, 76: 104972.

[2] [2] DAI B Y, FANG J J, YU Y R, et al. Construction of infrared- light-responsive photoinduced carriers driver for enhanced photocatalytic hydrogen evolution[J]. Adv Mater, 2020, 32(12): 1906361.

[3] [3] SHEN S H, GUO P H, ZHAO L, et al. Insights into photoluminescence property and photocatalytic activity of cubic and rhombohedral ZnIn2S4[J]. J Solid State Chem, 2011, 184(8): 2250-2256.

[4] [4] QIU J H, LI M, YANG L Y, et al. Facile construction of three-dimensional netted ZnIn2S4 by cellulose nanofibrils for efficiently photocatalytic reduction of Cr(VI)[J]. Chem Eng J, 2019, 375: 1385-8947.

[5] [5] JIANG Y, CHEN H Y, LI J Y, et al. Z-scheme 2D/2D heterojunction of CsPbBr3/Bi2WO6 for improved photocatalytic CO2 reduction[J]. Adv Funct Mater, 2020, 30(50): 2004293.

[6] [6] WANG L B, CHENG B, ZHANG L Y, et al. In situ irradiated XPS investigation on S-scheme TiO2@ZnIn2S4 photocatalyst for efficient photocatalytic CO2 reduction[J]. Small, 2021, 17(41): 2103447.

[7] [7] YANG H. A short review on heterojunction photocatalysts: Carrier transfer behavior and photocatalytic mechanisms[J]. Mater Res Bull, 2021, 142: 111406.

[8] [8] XU Q L, ZHANG L Y, CHENG B, et al. S-scheme heterojunction photocatalyst[J]. Chem, 2020, 6(7): 1543-1559.

[9] [9] LI J M, WU C C, LI J, et al. 1D/2D TiO2/ZnIn2S4 S-scheme heterojunction photocatalyst for efficient hydrogen evolution[J]. Chin J Catal, 2022, 43(2): 339-349.

[10] [10] ZHANG L Y, ZHANG J J, YU H G, et al. Emerging S-scheme photocatalyst[J]. Adv Mater, 2022, 34(11): 2107668.

[11] [11] XU Q L, WAGEH S, Al-GHAMDI A A, et al. Design principle of S-scheme heterojunction photocatalyst[J]. J Mater Sci Technol, 2022, 124: 171-173.

[12] [12] LI Y, ZHANG X L, LIU D. Recent developments of perylene diimide (PDI) supramolecular photocatalysts: A review[J]. J Photoch Photobio C, 2021, 48: 100436.

[13] [13] YANG J, JING J F, LI W L, et al. Electron donor-acceptor interface of TPPS/PDI boosting charge transfer for efficient photocatalytic hydrogen evolution[J]. Adv Sci, 2022, 9(11): 2201134.

[14] [14] LEE S G, KANG M J, PARK M, et al. Selective photocatalytic conversion of benzyl alcohol to benzaldehyde or deoxybenzoin over ion-exchanged CdS[J]. Appl Catal B Environ., 2022, 304: 120967.

[15] [15] LI H, QIN F, YANG Z P, et al. New reaction pathway induced by plasmon for selective benzyl alcohol oxidation on BiOCl possessing oxygen vacancies[J]. J Am Chem Soc, 2017, 139(9): 3513-3521.

[16] [16] LI Y Y, FANG Y, CAO Z L, et al. Construction of g-C3N4/PDI@MOF heterojunctions for the highly efficient visible light-driven degradation of pharmaceutical and phenolic micropollutants[J]. Appl Catal B Environ, 2019, 250: 150-162.

[17] [17] XIONG Z, HOU Y D, YUAN R S, et al. Hollow NiCo2S4 nanospheres as a cocatalyst to support ZnIn2S4 nanosheets for visible-light-driven hydrogen production[J]. Acta Phys-Chim Sin, 2022, 38(7): 2111021.

[18] [18] GAO Q Z, XU J, WANG Z P, et al. Enhanced visible photocatalytic oxidation activity of perylene diimide/g-C3N4 n-n heterojunction via π-π interaction and interfacial charge separation[J]. Appl Catal B Environ, 2020, 271: 118933.

[19] [19] WANG J, LIU D, ZHU Y F, et al. Supramolecular packing dominant photocatalytic oxidation and anticancer performance of PDI[J]. Appl Catal B Environ, 2018, 231: 251-261.

[20] [20] SHAO Y Y, HU J D, YANG T Y, et al. Significantly enhanced photocatalytic in-situ H2O2 production and consumption activities for efficient sterilization by ZnIn2S4/g-C3N4 heterojunction[J]. Carbon, 2022, 190: 337-347.

[21] [21] CAI T, ZENG W G, LIU Y T, et al. A promising inorganic-organic Z-scheme photocatalyst Ag3PO4/PDI supermolecule with enhanced photoactivity and photostability for environmental remediation[J]. Appl Catal B Environ, 2020, 263: 118327.

[22] [22] PRASAD C, TANG H, LIU Q Q, et al. A latest overview on photocatalytic application of g-C3N4 based nanostructured materials for hydrogen production[J]. Int J Hydrog Energy, 2020, 45(1): 337-379.

[23] [23] WANG R, SHEN J, ZHANG W J, et al. Build-in electric field induced step-scheme TiO2/W18O49 heterojunction for enhanced photocatalytic activity under visible-light irradiation[J]. Ceram Int, 2020, 46(1): 23-30.

[24] [24] PENG J J, SHEN J, YU X H, et al. Construction of LSPR-enhanced 0D/2D CdS/MoO3-x S-scheme heterojunctions for visible-light-driven photocatalytic H2 evolution[J]. Chin J Catal, 2021, 42(1): 87-96.

[25] [25] MKHALID I A, MOHAMED R M, ALHADDAD M, et al. S-scheme mesoporous Li2MnO3/g-C3N4 heterojunctions as efficient photocatalysts for the mineralization of trichloroethylene in aqueous media[J]. J Colloid Interface Sci, 2022, 614: 160-171.

[26] [26] MU F H, DAI B L, WU Y H, et al. 2D/3D S-scheme heterojunction of carbon nitride/iodine-deficient bismuth oxyiodide for photocatalytic hydrogen production and bisphenol A degradation[J]. J Colloid Interface Sci, 2022, 612: 722-736.

[27] [27] HONG X Y, YU X H, WANG L L, et al. Lattice-matched CoP/CoS2 heterostructure cocatalyst to boost photocatalytic H2 generation[J]. Inorg Chem, 2021, 60(16): 12506-12516.

[28] [28] SU H W, YU X H, WANG W K, et al. 2D bimetallic Ni-Co hydroxide monolayer cocatalyst for boosting photocatalytic H2 evolution[J]. Chem Commun, 2022, 58: 6180-6183.