[1] MANEERUNG T, KAWI S, DAI Y, et al.Sustainable biodiesel production via transesterification of waste cooking oil by using CaO catalysts prepared from chicken manure[J]. Energy conversion and management, 2016, 123: 487-497. [2] FONSECA J M,TELEKEN J G,CINQUE A D E, et al. Biodiesel from waste frying oils: methods of production and purification[J]. Energy conversion and management, 2019, 184: 205-218. [3] NAIK S N, GOUD V V,ROUT P K,et al.Production of first and second generation biofuels: a comprehensive review[J]. Renewable and sustainable energy reviews, 2010, 14(2): 578-597. [4] BLAKEY S, RYE L, WILSON C W.Aviation gas turbine alternative fuels: a review[J] Proceedings of the combustion institute, 2011, 33(2): 2863-2885. [5] LEE E, YUN S, PARK Y K, et al.Selective hydroisomerization of n-dodecane over platinum supported on SAPO-11[J]. Journal of industrial and engineering chemistry, 2014, 20(3): 775-780. [6] SANNA A, VISPUTE T P, HUBER G W.Hydrodeoxygenation of the aqueous fraction of bio-oil with Ru/C and Pt/C catalysts[J]. Applied catalysis B: environmental, 2015, 165: 446-456. [7] LI J, WANG S, LIU H Y, et al.Effective hydrodeoxygenation of stearic acid and cyperus esculentus oil into liquid alkanes over nitrogen-modified carbon nanotube-supported ruthenium catalysts[J]. Chemistry select, 2017, 2(1): 33-41. [8] THUNYARATCHATANON C, LUENGNARUEMITCHAI A, CHOLLACOOP N, et al.Catalytic upgrading of soybean oil methyl esters by partial hydrogenation using Pd catalysts[J]. Fuel, 2016, 163: 8-16. [9] SNARE M, KUBIČKOVÁ I, MÄKI-ARVELA P, et al. Heterogeneous catalytic deoxygenation of stearic acid for production of biodiesel[J]. Industrial & engineering chemistry research, 2006, 45(16): 5708-5715. [10] RABAEV M, LANDAU M V, VIDRUK-NEHEMYA R, et al.Conversion of vegetable oils on Pt/Al2O3/SAPO-11 to diesel and jet fuels containing aromatics[J]. Fuel, 2015, 161: 287-294. [11] HAN J X, SUN H, DING Y Q, et al.Palladium-catalyzed decarboxylation of higher aliphatic esters: towards a new protocol to the second generation biodiesel production[J]. Green chemistry, 2010, 12(3): 463-467. [12] 程军, 张曦, 刘建峰, 等. 镍基介孔Y催化微藻生物柴油制航空燃油[J]. 太阳能学报, 2020, 41(5): 230-234. CHENG J, ZHANG X, LIU J F, et al.Catalytic hydroprocessing of microalgae biodiesel to renewable jet fuels over Ni/meso-Y difunctional catalyst[J]. Acta energiae solaris sinica, 2020, 41(5): 230-234. [13] KUBIČKA D, KALUŽA L. Deoxygenation of vegetable oils over sulfided Ni, Mo and NiMo catalysts[J]. Applied catalysis A: general, 2010, 372(2): 199-208. [14] ZHANG H P, LIN H F, ZHENG Y. The role of cobalt and nickel in deoxygenation of vegetable oils[J]. Applied catalysis B: environmental, 2014, 160-161: 415-422. [15] KALUŽA L, KUBIČKA D. The comparison of Co, Ni, Mo, CoMo and NiMo sulfided catalysts in rapeseed oil hydrodeoxygenation[J]. Reaction kinetics, mechanisms and catalysis, 2017, 122(1): 333-341. [16] KUBIČKA D, HORÁČEK J, SETNIČKA M, et al. Effect of support-active phase interactions on the catalyst activity and selectivity in deoxygenation of triglycerides[J]. Applied catalysis B: environmental, 2014, 145: 101-107. [17] MA B, ZHAO C.High-grade diesel production by hydrodeoxygenation of palm oil over a hierarchically structured Ni/HBEA catalyst[J]. Green chemistry, 2015, 17(3): 1692-1701. [18] CHENG J, LI T, HUANG R, et al.Optimizing catalysis conditions to decrease aromatic hydrocarbons and increase alkanes for improving jet biofuel quality[J]. Bioresource technology, 2014, 158: 378-382. [19] SHI Y, CAO Y, DUAN Y, et al.Upgrading of palmitic acid to iso-alkanes over bi-functional Mo/ZSM-22 catalysts[J]. Green chemistry, 2016, 18(17): 4633-4648. [20] XIA W S, HOU Y H,CHANG G,et al.Partial oxidation of methane into syngas(H2+CO) over effective high-dispersed Ni/SiO2 catalysts synthesized by a sol-gel method[J]. International journal of hydrogen energy, 2012, 37(10): 8343-8353. [21] REN J, CAO J P, ZHAO X Y, et al.Preparation of high-dispersion Ni/C catalyst using modified lignite as carbon precursor for catalytic reforming of biomass volatiles[J]. Fuel, 2017, 202: 345-351. [22] SONG W, ZHAO C, LERCHER J A.Importance of size and distribution of Ni nanoparticles for the hydrodeoxygenation of microalgae oil[J]. Chemistry-a European journal, 2013, 19(30): 9833-9842. [23] PING E W, WALLACE R, PIERSON J, et al.Highly dispersed palladium nanoparticles on ultra-porous silica mesocellular foam for the catalytic decarboxylation of stearic acid[J]. Microporous and mesoporous materials, 2010, 132(1): 174-180. [24] ESCOLA J M, SERRANO D P, AGUADO J,et al.Hydroreforming of the LDPE thermal cracking oil over hierarchical Ni/Beta catalysts with different Ni particle size distributions[J]. Industrial & engineering chemistry research, 2015, 54(26): 6660-6668. [25] SANTILLAN-JIMENEZ E, MORGAN T,LACNY J, et al.Catalytic deoxygenation of triglycerides and fatty acids to hydrocarbons over carbon-supported nickel[J]. Fuel, 2013, 103: 1010-1017. [26] CHEN L, FU J, YANG L, et al.Catalytic hydrotreatment of fatty acid methyl esters to diesel-like alkanes over Hβ zeolite-supported nickel catalysts[J]. ChemCatChem, 2014, 6(12): 3482-3492. [27] JIANG T, WANG T J, MA L L, et al.Investigation on the xylitol aqueous-phase reforming performance for pentane production over Pt/HZSM-5 and Ni/HZSM-5 catalysts[J]. Applied energy, 2012, 90(1): 51-57. [28] NUMWONG N, LUENGNARUEMITCHAI A, CHOLLACOOP N, et al. Effect of SiO2 pore size on partial hydrogenation of rapeseed oil-derived FAMEs[J]. Applied catalysis A: general, 2012, 441-442: 72-78. [29] SHOMCHOAM B, YOOSUK B.Eco-friendly lubricant by partial hydrogenation of palm oil over Pd/γ-Al2O3 catalyst[J]. Industrial crops and products, 2014, 62: 395-399. [30] IIDA H, ITOH D, MINOWA S,et al.Hydrogenation of soybean oil over various platinum catalysts: effects of support materials on trans fatty acid levels[J]. Catalysis communications, 2015, 62: 1-5. [31] NOHAIR B, ESPECEL C, LAFAYE G, et al.Palladium supported catalysts for the selective hydrogenation of sunflower oil[J]. Journal of molecular catalysis A: chemical, 2005, 229(1-2): 117-126. [32] PENG B X, ZHAO C, KASAKOV S, et al.Manipulating catalytic pathways: deoxygenation of palmitic acid on multifunctional catalysts[J]. Chemistry-A European journal, 2013, 19(15): 4732-4741. [33] HU Y F, WANG X S, GUO X W, et al.Effects of channel structure and acidity of molecular sieves in hydroisomerization of n-octane over bi-functional catalysts[J]. Catalysis letters, 2005, 100(1): 59-65. [34] VERMA D, RANA B S, KUMAR R, et al.Diesel and aviation kerosene with desired aromatics from hydroprocessing of jatropha oil over hydrogenation catalysts supported on hierarchical mesoporous SAPO-11[J]. Applied catalysis A: general, 2015, 490: 108-116. [35] XING G H, LIU S Y, GUAN Q X, et al.Investigation on hydroisomerization and hydrocracking of C15-C18 n-alkanes utilizing a hollow tubular Ni-Mo/SAPO-11 catalyst with high selectivity of jet fuel[J]. Catalysis today, 2018, 336: 109-116. [36] COONRADT H L, GARWOOD W E.Mechanism of hydrocracking reactions of paraffins and olefins[J]. Industrial & engineering chemistry research, 1964, 3: 38-45. [37] 林励吾, 张馥良. 中国科学院化学物理研究所研究报刊第1集[M]. 北京: 科学出版社, 1964. LIN L W, ZHANG F L.Journal of institute of chemical physics, Chinese academy of sciences, episode 1[M]. Beijing: Science Press, 1964. [38] LIN L W, LIANG D B, WANG Q X, et al.Research and development of catalytic processes for petroleum and natural gas conversions in the Dalian Institute of Chemical Physics[J]. Catalysis today, 1999, 51(1): 59-72. [39] GALPERIN L B, BRADLEY S A, MEZZA T M.Hydroisomerization of n-decane in the presence of sulfur: effect of metal-acid balance and metal location[J]. Applied catalysis A: general, 2001, 219(1-2): 79-88. [40] CHEN X Y, JIA M, LIU G Z, et al.Catalytic performance of grafted Al-MCM-41 in hydroisomerization of n-dodecane[J]. Applied surface science, 2010, 256(20): 5856-5861. [41] LIU S Y, REN J, ZHU S J, et al.Synthesis and characterization of the Fe-substituted ZSM-22 zeolite catalyst with high n-dodecane isomerization performance[J]. Journal of catalysis, 2015, 330: 485-496. [42] LESTARI S, SIMAKOVA I, TOKAREV A, et al.Synthesis of biodiesel via deoxygenation of stearic acid over supported Pd/C catalyst[J]. Catalysis letters, 2008, 122(3): 247-251. [43] PENG B X, YAO Y, ZHAO C, et al.Towards quantitative conversion of microalgae oil to diesel-range alkanes with bifunctional catalysts[J]. Angewandte chemie international edition, 2012, 51(9): 2072-2075. [44] XING S Y, LYU P M, WANG J Y, et al.One-step hydroprocessing of fatty acids into renewable aromatic hydrocarbons over Ni/HZSM-5: insights into the major reaction pathways[J]. Physical chemistry chemical physics, 2017, 19(4): 2961-2973. [45] LI M, XING S Y, YANG L M, et al.Nickel-loaded ZSM-5 catalysed hydrogenation of oleic acid: the game between acid sites and metal centres[J]. Applied catalysis A: general, 2019, 587: 117112. [46] ZHAO S, LI M F, CHU Y, et al.Hydroconversion of methyl laurate as a model compound to hydrocarbons on bifunctional Ni2P/SAPO-11: simultaneous comparison with the performance of Ni/SAPO-11[J]. Energy fuels, 2014, 28(11): 7122-7132. [47] YANG L M, XING S Y, SUN H Z, et al.Citric-acid-induced mesoporous SAPO-11 loaded with highly dispersed nickel for enhanced hydroisomerization of oleic acid to iso-alkanes[J]. Fuel processing technology, 2019, 187: 52-62. [48] LI X Y, CHEN Y B, HAO Y J, et al.Optimization of aviation kerosene from one-step hydrotreatment of catalytic Jatropha oil over SDBS-Pt/SAPO-11 by response surface methodology[J]. Renewable energy, 2019, 139: 551-559. [49] BATALHA N, PINARD L, BOUCHY C, et al.n-hexadecane hydroisomerization over Pt-HBEA catalysts. Quantification and effect of the intimacy between metal and protonic sites[J]. Journal of catalysis, 2013, 307: 122-131. [50] OZAKI A, KIMURA K.The effective site on acid catalysts revealed in n-butene isomerization[J]. Journal of catalysis, 1964, 3(5): 395-405. [51] WEITKAMP J, JACOBS P A, MARTENS J A.Isomerization and hydrocracking of C9 through C16 n-alkanes on Pt/HZSM-5 zeolite[J]. Applied catalysis, 1983, 8(1): 123-141. [52] WEISZ P B, SWEGLER E W.Stepwise reaction on separate catalytic centers: isomerization of saturated hydrocarbons[J]. Science, 1957, 126(3262): 31-32. [53] SIE S T.Acid-catalyzed cracking of paraffinic hydrocarbons. 3. Evidence for the protonated cyclopropane mechanism from hydrocracking/hydroisomerization experiments[J]. Industrial & engineering chemistry research, 1993, 32: 403-408. [54] 张淼. ZSM-48分子筛的合成、改性及十六烷加氢异构性能[D]. 大连: 大连理工大学, 2017. ZHANG M.Synthesis and modification of ZSM-48 zeolitess and their performance for hydroisomerization of hexadecane[D]. Dalian: Dalian University of Technology, 2017. [55] CLAUDE M C, MARTENS J A.Monomethyl-branching of long n-alkanes in the range from decane to tetracosane on Pt/H-ZSM-22 bifunctional catalyst[J]. Journal of catalysis, 2000, 190(1): 39-48. |