Dongqiang ZHANG, Huihui LU, Na SU, Guixian LI, Dong JI, Xinhong ZHAO. Modulation of SAPO-34 Property with Activated Seeds and Its Enhanced Lifetime in Methanol to Olefins Reaction[J]. Journal of Inorganic Materials, 2021, 36(1): 101.
参考文献
[1]CORMAA. Inorganic solid acids and their use in acid-catalyzed hydrocarbon reactions. , 1995,95(3):559-614.
[3]WEITKAMPJ, HUNGERM. Acid and Base Catalysis on Zeolites//ČEJKA J, van BEKKUM H, CORMA A, et al. , 2007: 787-835.
[4]STöCKERM. Methanol-to-hydrocarbons: catalytic materials and their behavior. , 1999,29:3-48.
[5]YANGM, FAND, WEIY, et al. Recent progress in methanol- to-olefins (MTO) catalysts. , 2019,31:1902181.
[6]SEOG, KIM JH, JANG HG. Methanol-to-olefin conversion over zeolite catalysts: active intermediates and deactivation. , 2013,17(3/4):103-118.
[7]SUNQ, XIEZ, YUJ. The state-of-the-art synthetic strategies for SAPO-34 zeolite catalysts in methanol-to-olefin conversion. , 2018,5(4):542-558.
[8]VAN SPEYBROECKV, DE WISPELAEREK, VAN DER MYNSBRUGGEJ, et al. First principle chemical kinetics in zeolites: the methanol-to-olefin process as a case study. , 2014,43(21):7326-7357.
[9]LIANGJ, LIH, ZHAOS, et al. Characteristics and performance of SAPO-34 catalyst for methanol-to-olefin conversion. , 1990,64:31-40.
[10]WUP, YANGM, ZHANGW, et al. Synthesis of SAPO-34 nanoaggregates with the assistance of an inexpensive three-in-one non-surfactant organosilane. , 2017,53(36):4985-4988.
[11]AGHAEIE, HAGHIGHIM. Effect of crystallization time on properties and catalytic performance of nanostructured SAPO-34 molecular sieve synthesized at high temperatures for conversion of methanol to light olefins. , 2015,269:358-370.
[12]LIZ, MARTINEZ-TRIGUEROJ, CONCEPCIONP, et al. Methanol to olefins: activity and stability of nanosized SAPO-34 molecular sieves and control of selectivity by silicon distribution. , 2013,15(35):14670-14680.
[13]WANGC, YANGM, TIANP, et al. Dual template-directed synthesis of SAPO-34 nanosheet assemblies with improved stability in the methanol to olefins reaction. , 2015,3(10):5608-5616.
[14]WANGP, LÜA, HUJ, et al. The synthesis of SAPO-34 with mixed template and its catalytic performance for methanol to olefins reaction. , 2012,152:178-184.
[15]SUNQ, WANGN, XID, et al. Organosilane surfactant-directed synthesis of hierarchical porous SAPO-34 catalysts with excellent MTO performance. , 2014,50(49):6502-6505.
[16]GUISNETM, COSTAL, RIBEIRO FR. Prevention of zeolite deactivation by coking. , 2009,305:69-83.
[17]DAIW, LIN, LIL, et al. Unexpected methanol-to-olefin conversion activity of low-silica aluminophosphate molecular sieves. , 2011,16(1):124-127.
[18]OLSBYEU, BJøRGEN M, SVELLE S,et al. Mechanistic insight into the methanol-to-hydrocarbons reaction. , 2005,106(1):108-111.
[19]DAIW, WANGX, WUG, et al. Methanol-to-olefin conversion catalyzed by low-silica AlPO-34 with traces of Brønsted acid sites: combined catalytic and spectroscopic investigations. , 2012,4(9):1428-1435.
[20]DAHL IM, KOLBOES. On the reaction mechanism for hydrocarbon formation from methanol over SAPO-34: 2. Isotopic labeling studies of the co-reaction of propene and methanol. , 1996,161(1):304-309.
[21]HEREIJERS BP, BLEKENF, NILSEN MH, et al. Product shape selectivity dominates the methanol-to-olefins (MTO) reaction over H-SAPO-34 catalysts. , 2009,264(1):77-87.
[22]WILSONS, BARGERP. The characteristics of SAPO-34 which influence the conversion of methanol to light olefins. , 1999,29(1/2):117-126.
[23]DAHL IM, MOSTADH, AKPORIAYED, et al. Structural and chemical influences on the MTO reaction: a comparison of chabazite and SAPO-34 as MTO catalysts. , 1999,29(1/2):185-190.
[24]IZADBAKHSHA, FARHADIF, KHORASHEHF, et al. Effect of SAPO-34’s composition on its physico-chemical properties and deactivation in MTO process. , 2009,364(1):48-56.
[25]KANGM. Methanol conversion on metal-incorporated SAPO-34s (MeAPSO-34s). , 2000,160(2):437-444.
[26]MIRZAK, GHADIRIM, HAGHIGHIM, et al. Hydrothermal synthesize of modified Fe, Ag and K-SAPO-34 nanostructured catalysts used in methanol conversion to light olefins. , 2018,260:155-165.
[27]HUANGH, WANGH, ZHUH, et al. Enhanced ethene to propene ratio over Zn-modified SAPO-34 zeolites in methanol-to-olefin reaction. , 2019,9(9):2203-2210.
[28]INUIT, PHATANASRIS, MATSUDAH. Highly selective synthesis of ethene from methanol on a novel nickel- silicoaluminophosphate catalyst. , 1990, 205-206.
[29]VAN NIEKERK MJ, FLETCHER JC, O'CONNOR CT. Effect of catalyst modification on the conversion of methanol to light olefins over SAPO-34. , 1996,138:135-145.
[30]MEES FD, DER VOORT P V, COOL P,et al. Controlled reduction of the acid site density of SAPO-34 molecular sieve by means of silanation and disilanation. , 2003,107(14):3161-3167.
[31]HIDAKAT, YOKOSEE. Catalysts for Methanol Conversion Reactions. , TW87111286A, 1997
[32]SUNQ, WANGN, BAIR, et al. Seeding induced nano-sized hierarchical SAPO-34 zeolites: cost-effective synthesis and superior MTO performance. , 2016,4(39):14978-14982.
[33]GAOB, YANGM, QIAOY, et al. A low-temperature approach to synthesize low-silica SAPO-34 nanocrystals and their application in the methanol-to-olefins (MTO) reaction. , 2016,6(20):7569-7578.
[34]WUQ, MENGX, GAOX, et al. Solvent-free synthesis of zeolites: mechanism and utility. , 2018,51(6):1396-1403.
[35]JINY, SUNQ, QIG, et al. Solvent-free synthesis of silicoaluminophosphate zeolites. , 2013,52(35):9172-9175.
[36]NAJAFIN, ASKARIS, HALLADJR. Hydrothermal synthesis of nanosized SAPO-34 molecular sieves by different combinations of multi templates. , 2014,254:324-330.
[37]MENGX, JINY, SUNQ, et al. Solid-state grinding syntheis for SAPO-34. . 4, 2013.
[38]MAJANOG, DARWICHEA, MINTOVAS, et al. Seed-induced crystallization of nanosized Na-ZSM-5 crystals. , 2009,48(15):7084-7091.
[39]RENN, YANG ZJ, LV XC, et al. A seed surface crystallization approach for rapid synthesis of submicron ZSM-5 zeolite with controllable crystal size and morphology. , 2010,131(1):103-114.
[40]QINZ, PINARDL, BENGHALEM MA, et al. Preparation of single crystals “house-of-cards”-like ZSM-5 and their performance in ethanol-to-hydrocarbons conversion. , 2019,31(13):4639-4648.
[41]LYUM, YANGC, LIUZ, et al. Atmospheric pressure synthesis of nano-scale SAPO-34 catalysts for effective conversion of methanol to light olefins. , 2019,3(11):3101-3108.
[42]SENA FC, DESOUZA B F, DEALMEIDA N C, et al. Influence of framework composition over SAPO-34 and MeAPSO-34 acidity. , 2011,406(1):59-62.
[43]WANGP, YANGD, JIE HU, et al. Synthesis of SAPO-34 with small and tunable crystallite size by two-step hydrothermal crystallization and its catalytic performance for MTO reaction. , 2013, 212: 62.e61-62.e68. SUNQ, MAY, WANGN, et al. High performance nanosheet-like silicoaluminophosphate molecular sieves: synthesis, 3D EDT structural analysis and MTO catalytic studies. , 2014,2(42):17828-17839.
WANGP, YANGD, JIE HU, et al. Synthesis of SAPO-34 with small and tunable crystallite size by two-step hydrothermal crystallization and its catalytic performance for MTO reaction. , 2013, 212: 62.e61-62.e68. SUNQ, MAY, WANGN, et al. High performance nanosheet-like silicoaluminophosphate molecular sieves: synthesis, 3D EDT structural analysis and MTO catalytic studies. , 2014,2(42):17828-17839.
张栋强, 路惠惠, 苏娜, 李贵贤, 季东, 赵新红. 活化晶种调节SAPO-34的性质及其对甲醇制烯烃反应催化寿命的增强[J]. 无机材料学报, 2021, 36(1): 101. Dongqiang ZHANG, Huihui LU, Na SU, Guixian LI, Dong JI, Xinhong ZHAO. Modulation of SAPO-34 Property with Activated Seeds and Its Enhanced Lifetime in Methanol to Olefins Reaction[J]. Journal of Inorganic Materials, 2021, 36(1): 101.