[5] [5] ARDAKANI S J, LIU X B, SMITH K J. Hydrogenation and ring opening of naphthalene on bulk and supported Mo2C catalysts［J］. Applied Catalysis A: General, 2007, 324: 9-19.

[6] [6] CHAREONPANICH M, ZHANG Z G, TOMITA A. Hydrocracking of aromatic hydrocarbons over USY-zeolite［J］. Energy & Fuels, 1996, 10(4): 927-931.

[9] [9] KOSTYNIUK A, BAJEC D, LIKOZAR B. Catalytic hydrocracking reactions of tetralin as aromatic biomass tar model compound to benzene/toluene/xylenes (BTX) over zeolites under ambient pressure conditions［J］. Journal of Industrial and Engineering Chemistry, 2021, 96: 130-143.

[10] [10] KOSTYNIUK A, BAJEC D, LIKOZAR B. Catalytic hydrocracking reactions of tetralin biomass tar model compound to benzene, toluene and xylenes (BTX) over metal-modified ZSM-5 in ambient pressure reactor［J］. Renewable Energy, 2022, 188: 240-255.

[11] [11] LEE J, CHOI Y, SHIN J, et al. Selective hydrocracking of tetralin for light aromatic hydrocarbons［J］. Catalysis Today, 2016, 265: 144-153.

[12] [12] XIAN X C, RAN C, YANG P, et al. Effect of the acidity of HZSM-5/MCM-41 hierarchical zeolite on its catalytic performance in supercritical catalytic cracking of n-dodecane: experiments and mechanism［J］. Catalysis Science & Technology, 2018, 8(16): 4241-4256.

[13] [13] NIU X J, GAO J, MIAO Q, et al. Influence of preparation method on the performance of Zn-containing HZSM-5 catalysts in methanol-to-aromatics［J］. Microporous and Mesoporous Materials, 2014, 197: 252-261.

[15] [15] ZHANG C D, KWAK G, LEE Y J, et al. Light hydrocarbons to BTEX aromatics over Zn-modified hierarchical ZSM-5 combined with enhanced catalytic activity and stability［J］. Microporous and Mesoporous Materials, 2019, 284: 316-326.

[16] [16] ZHANG Y W, ZHOU Y M, HUANG L, et al. Structure and catalytic properties of the Zn-modified ZSM-5 supported platinum catalyst for propane dehydrogenation［J］. Chemical Engineering Journal, 2015, 270: 352-361.

[17] [17] JING H J, YANG F K, XIA Y M, et al. A study on the selectivity of methanol aromatization［J］. Petroleum Science and Technology, 2012, 30(16): 1737-1746.

[19] [19] SHEN Z B, HE P, WANG A G, et al. Conversion of naphthalene as model compound of polyaromatics to mono-aromatic hydrocarbons under the mixed hydrogen and methane atmosphere［J］. Fuel, 2019, 243: 469-477.

[22] [22] WU T, CHEN S L, YUAN G M, et al. High-selective-hydrogenation activity of W/Beta catalyst in hydrocracking of 1-methylnaphalene to benzene, toluene and xylene［J］. Fuel, 2018, 234: 1015-1025.

[24] [24] LEE S U, LEE Y J, KIM J R, et al. Tactical control of Ni-loading over W-supported Beta zeolite catalyst for selective ring opening of 1-methylnaphthalene［J］. Journal of Industrial and Engineering Chemistry, 2018, 66: 279-287.

[27] [27] CAO Z K, ZHANG X, XU C M, et al. The synthesis of Al-SBA-16 materials with a novel method and their catalytic application on hydrogenation for FCC diesel［J］. Energy & Fuels, 2017, 31(1): 805-814.

[28] [28] LEE S U, LEE Y J, KIM J R, et al. Rational synthesis of silylated Beta zeolites and selective ring opening of 1-methylnaphthalene over the NiW-supported catalysts［J］. Applied Catalysis B: Environmental, 2017, 219: 1-9.

[29] [29] EBRAHIMINEJAD M, KARIMZADEH R. Hydrocracking and hydrodesulfurization of diesel over zeolite beta-containing NiMo supported on activated red mud［J］. Advanced Powder Technology, 2019, 30(8): 1450-1461.

[30] [30] DIK P P, DANILOVA I G, GOLUBEV I S, et al. Hydrocracking of vacuum gas oil over NiMo/zeolite-Al2O3: Influence of zeolite properties［J］. Fuel, 2019, 237: 178-190.

[31] [31] SUBRAMANI T, THIMMARAYAN G, BALRAJ B, et al. Surfactants assisted synthesis of WO3 nanoparticles with improved photocatalytic and antibacterial activity: a strong impact of morphology［J］. Inorganic Chemistry Communications, 2022, 142: 109709.

[32] [32] LIU N, DING S L, CUI Y M, et al. Optimizing activity of tungsten oxides for 1-butene metathesis by depositing silica on γ-alumina support［J］. Chemical Engineering Research and Design, 2013, 91(3): 573-580.

[33] [33] ANGGORO D D, AMIN N A S. Methane to liquid hydrocarbons over tungsten-ZSM-5 and tungsten loaded Cu/ZSM-5 catalysts［J］. Journal of Natural Gas Chemistry, 2006, 15(4): 340-347.

[34] [34] LIU J X, HE D H. Transformation of CO2 with glycerol to glycerol carbonate by a novel ZnWO4-ZnO catalyst［J］. Journal of CO2 Utilization, 2018, 26: 370-379.