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U. Olsbye, S. Svelle, M. Bjørgen, P. Beato, T. Janssens, F. Joensen, S. Bordiga, K. Lillerud (2012)
Conversion of methanol to hydrocarbons: how zeolite cavity and pore size controls product selectivity.Angewandte Chemie, 51 24
G. Bellussi, P. Pollesel (2005)
Industrial applications of zeolite catalysis: production and uses of light olefinsStudies in Surface Science and Catalysis, 158
Xiangxue Zhu, Xiangxue Zhu, Shenglin Liu, Yueqin Song, Longya Xu (2005)
Catalytic cracking of C4 alkenes to propene and ethene : Influences of zeolites pore structures and Si/Al2 ratiosApplied Catalysis A-general, 288
F. Cavani, N. Ballarini, A. Cericola (2007)
Oxidative dehydrogenation of ethane and propane : How far from commercial implementation?Catalysis Today, 127
C. González-Rugerio, T. Keller, J. Pilarczyk, W. Sałacki, A. Górak (2012)
TAEE synthesis from isoamylenes and ethanol by catalytic distillation: Pilot plant experiments and model validationFuel Processing Technology, 102
O. Bortnovský, P. Sazama, B. Wichterlová (2005)
Cracking of pentenes to C2–C4 light olefins over zeolites and zeotypes: Role of topology and acid site strength and concentrationApplied Catalysis A-general, 287
F. Bleken, S. Chavan, U. Olsbye, M. Boltz, F. Ocampo, B. Louis (2012)
Conversion of methanol into light olefins over ZSM-5 zeolite: Strategy to enhance propene selectivityApplied Catalysis A-general, 447
S. Svelle, F. Joensen, J. Nerlov, U. Olsbye, K. Lillerud, S. Kolboe, M. Bjørgen (2006)
Conversion of methanol into hydrocarbons over zeolite H-ZSM-5: ethene formation is mechanistically separated from the formation of higher alkenes.Journal of the American Chemical Society, 128 46
E. Epelde, J. Santos, P. Florian, A. Aguayo, A. Gayubo, J. Bilbao, P. Castaño (2015)
Controlling coke deactivation and cracking selectivity of MFI zeolite by H3PO4 or KOH modificationApplied Catalysis A-general, 505
T. Janssens, S. Svelle, U. Olsbye (2013)
Kinetic modeling of deactivation profiles in the methanol-to-hydrocarbons (MTH) reaction: A combined autocatalytic–hydrocarbon pool approachJournal of Catalysis, 308
C. Emeis (1993)
Determination of integrated molar extinction coefficients for infrared absorption bands of pyridine adsorbed on solid acid catalystsJournal of Catalysis, 141
Farshid Mohammadparast, R. Halladj, S. Askari (2015)
The Crystal Size Effect of Nano-Sized ZSM-5 in the Catalytic Performance of Petrochemical Processes: A ReviewChemical Engineering Communications, 202
Dániel Fodor, A. Redondo, F. Krumeich, J. Bokhoven (2015)
Role of Defects in Pore Formation in MFI ZeolitesJournal of Physical Chemistry C, 119
F. Patcas (2005)
The methanol-to-olefins conversion over zeolite-coated ceramic foamsJournal of Catalysis, 231
Joongwon Lee, Ung Hong, Sunhwan Hwang, M. Youn, I. Song (2013)
Catalytic cracking of C5 raffinate to light olefins over lanthanum-containing phosphorous-modified porous ZSM-5: Effect of lanthanum contentFuel Processing Technology, 109
P. Arudra, T. Bhuiyan, Muhammad Akhtar, A. Aitani, S. Al-Khattaf, H. Hattori (2014)
Silicalite-1 As Efficient Catalyst for Production of Propene from 1-ButeneACS Catalysis, 4
Long-Fei Lin, Shufang Zhao, D. Zhang, Huiying Fan, Yue Liu, Mingyang He (2015)
Acid Strength Controlled Reaction Pathways for the Catalytic Cracking of 1-Pentene to Propene over ZSM-5ACS Catalysis, 5
Katia Barbera, F. Bonino, S. Bordiga, T. Janssens, P. Beato (2011)
Structure–deactivation relationship for ZSM-5 catalysts governed by framework defectsJournal of Catalysis, 280
A. Miyaji, Y. Sakamoto, Y. Iwase, T. Yashima, R. Koide, Ken Motokura, T. Baba (2013)
Selective production of ethylene and propylene via monomolecular cracking of pentene over proton-exchanged zeolites: Pentene cracking mechanism determined by spatial volume of zeolite cavityJournal of Catalysis, 302
P. Benito, A. Gayubo, A. Aguayo, M. Castilla, J. Bilbao (1996)
Concentration-Dependent Kinetic Model for Catalyst Deactivation in the MTG ProcessIndustrial & Engineering Chemistry Research, 35
I. Yarulina, J. Goetze, C. Gücüyener, L. Thiel, A. Dikhtiarenko, J. Ruiz‐Martinez, B. Weckhuysen, J. Gascón, F. Kapteijn (2016)
Methanol-to-olefins process over zeolite catalysts with DDR topology: effect of composition and structural defects on catalytic performanceCatalysis Science & Technology, 6
Stefan Schallmoser, Takaaki Ikuno, Manuel Wagenhofer, R. Kolvenbach, G. Haller, M. Sanchez-Sanchez, J. Lercher (2014)
Impact of the local environment of Brønsted acid sites in ZSM-5 on the catalytic activity in n-pentane crackingJournal of Catalysis, 316
W. Vermeiren, J.-P. Gilson (2009)
Impact of Zeolites on the Petroleum and Petrochemical IndustryTopics in Catalysis, 52
Nina-Luisa Michels, S. Mitchell, J. Pérez–Ramírez (2014)
Effects of Binders on the Performance of Shaped Hierarchical MFI Zeolites in Methanol-to-HydrocarbonsACS Catalysis, 4
M. Milina, S. Mitchell, David Cooke, P. Crivelli, J. Pérez–Ramírez (2015)
Impact of pore connectivity on the design of long-lived zeolite catalysts.Angewandte Chemie, 54 5
S. Mitchell, A. Pinar, J. Kenvin, P. Crivelli, J. Kärger, J. Pérez–Ramírez (2015)
Structural analysis of hierarchically organized zeolitesNature Communications, 6
T. Degnan (2007)
Recent progress in the development of zeolitic catalysts for the petroleum refining and petrochemical manufacturing industriesStudies in Surface Science and Catalysis, 170
C. Chen, S. Rangarajan, Ian Hill, A. Bhan (2014)
Kinetics and Thermochemistry of C4–C6 Olefin Cracking on H-ZSM-5ACS Catalysis, 4
J. Buchanan, J. Santiesteban, Haag Otto (1996)
Mechanistic considerations in acid-catalyzed cracking of olefinsJournal of Catalysis, 158
Rachit Khare, Dean Millar, A. Bhan (2015)
A mechanistic basis for the effects of crystallite size on light olefin selectivity in methanol-to-hydrocarbons conversion on MFIJournal of Catalysis, 321
A. Farshi, F. Shaiyegh, S. Burogerdi, A. Dehgan (2011)
FCC Process Role in Propylene DemandsPetroleum Science and Technology, 29
J. Mol (2004)
Industrial applications of olefin metathesisJournal of Molecular Catalysis A-chemical, 213
M. Holm, S. Svelle, F. Joensen, P. Beato, C. Christensen, S. Bordiga, M. Bjørgen (2009)
Assessing the acid properties of desilicated ZSM-5 by FTIR using CO and 2,4,6-trimethylpyridine (collidine) as molecular probesApplied Catalysis A-general, 356
Jeongnam Kim, Minkee Choi, R. Ryoo (2010)
Effect of mesoporosity against the deactivation of MFI zeolite catalyst during the methanol-to-hydrocarbon conversion processJournal of Catalysis, 269
S. Ivanova, C. Lebrun, E. Vanhaecke, C. Pham‐Huu, B. Louis (2009)
Influence of the zeolite synthesis route on its catalytic properties in the methanol to olefin reactionJournal of Catalysis, 265
Longfei Lin, Cai-Xia Qiu, Zhuo Zuoxi, Dawei Zhang, Shufang Zhao, Haihong Wu, Yue Liu, M. He (2014)
Acid strength controlled reaction pathways for the catalytic cracking of 1-butene to propene over ZSM-5Journal of Catalysis, 309
Teng Xue, Yi Wang, M. He (2012)
Facile synthesis of nano-sized NH4-ZSM-5 zeolitesMicroporous and Mesoporous Materials, 156
S. Bessell, D. Seddon (1987)
The conversion of ethene and propene to higher hydrocarbons over ZSM-5Journal of Catalysis, 105
H. Wittcoff, B. Reuben, Jeffery Plotkin (1996)
Industrial Organic Chemicals
Y. Kissin (2001)
CHEMICAL MECHANISMS OF CATALYTIC CRACKING OVER SOLID ACIDIC CATALYSTS: ALKANES AND ALKENESCatalysis Reviews, 43
M. Höchtl, A. Jentys, H. Vinek (2001)
Isomerization of 1-pentene over SAPO, CoAPO (AEL, AFI) molecular sieves and HZSM-5Applied Catalysis A-general, 207
Guoliang Zhao, J. Teng, Zaiku Xie, W. Jin, Weimin Yang, Qingling Chen, Yi Tang (2007)
Effect of phosphorus on HZSM-5 catalyst for C4-olefin cracking reactions to produce propyleneJournal of Catalysis, 248
N. Danilina, F. Krumeich, Stefano Castelanelli, J. Bokhoven (2010)
Where Are the Active Sites in Zeolites? Origin of Aluminum Zoning in ZSM-5Journal of Physical Chemistry C, 114
S. Mitchell, M. Milina, R. Verel, M. Hernández-Rodríguez, A. Pinar, L. McCusker, J. Pérez–Ramírez (2015)
Aluminum Redistribution during the Preparation of Hierarchical Zeolites by Desilication.Chemistry, 21 40
M. Milina, S. Mitchell, P. Crivelli, David Cooke, J. Pérez–Ramírez (2014)
Mesopore quality determines the lifetime of hierarchically structured zeolite catalystsNature Communications, 5
H. Wittcoff, B. Reuben, J. Plotkin (2012)
Industrial Organic Chemicals: Wittcoff/Industrial Organic Chemicals
Joongwon Lee, S. Park, Ung Hong, J. Jun, I. Song (2015)
Production of Light Olefins Through Catalytic Cracking of C5 Raffinate Over Surface-Modified ZSM-5 Catalyst.Journal of nanoscience and nanotechnology, 15 10
N. Rahimi, R. Karimzadeh (2011)
Catalytic cracking of hydrocarbons over modified ZSM-5 zeolites to produce light olefins: A reviewApplied Catalysis A-general, 398
P. Sazama, J. Dědeček, V. Gábová, B. Wichterlová, G. Spoto, S. Bordiga (2008)
Effect of aluminium distribution in the framework of ZSM-5 on hydrocarbon transformation. Cracking of 1-buteneJournal of Catalysis, 254
Zhengxing Qin, Louwanda Lakiss, L. Tosheva, J. Gilson, A. Vicente, C. Fernandez, V. Valtchev (2014)
Comparative Study of Nano‐ZSM‐5 Catalysts Synthesized in OH− and F− MediaAdvanced Functional Materials, 24
J. Abbot, B. Wojciechowski (1985)
The mechanism of catalytic cracking of n‐alkenes on ZSM‐5 zeoliteCanadian Journal of Chemical Engineering, 63
B. Gil, Ł. Mokrzycki, B. Sulikowski, Z. Olejniczak, S. Walas (2010)
Desilication of ZSM-5 and ZSM-12 zeolites : impact on textural, acidic and catalytic propertiesCatalysis Today, 152
M. Snyder, M. Tsapatsis (2007)
Hierarchical nanomanufacturing: from shaped zeolite nanoparticles to high-performance separation membranes.Angewandte Chemie, 46 40
Yong-ki Park, C. Lee, N. Kang, W. Choi, Sun Choi, Seung-Hoon Oh, Deuk Park (2010)
Catalytic Cracking of Lower-Valued Hydrocarbons for Producing Light OlefinsCatalysis Surveys from Asia, 14
M. Bjørgen, F. Joensen, M. Holm, U. Olsbye, K. Lillerud, S. Svelle (2008)
Methanol to gasoline over zeolite H-ZSM-5: Improved catalyst performance by treatment with NaOHApplied Catalysis A-general, 345
V. Nayak, V. Choudhary (1984)
Selective poisoning of stronger acid sites on HZSM-5 in the conversion of alcohols and olefins to aromaticsApplied Catalysis, 9
The selective cracking of low-value C5 olefins such as 2-methyl-2-butene (2M2B), a growing by-product of deep catalytic cracking, over ZSM-5 zeolites is an attractive route for the on-purpose production of ethylene and propylene. Yet, several aspects, including the deactivation behaviour and the effect of the crystal properties ( i.e. , the size, morphology, amount of defects, and mesoporosity) on the performance, still lack understanding. Here, the relative impact of these key crystal variables on the catalyst stability and selectivity is examined by preparing a series of tailored materials with equivalent acidic properties within the optimal range for this process. Specifically, zeolites with micron- and nanosized crystals of rounded-boat and coffin-shaped morphology and different defect concentrations are synthesised in hydroxide and fluoride media, whereas intracrystalline mesopores are subsequently introduced by their controlled desilication. In agreement with the comparable active site distributions, evaluation in 2M2B cracking evidences similar initial conversion and product distributions over all catalysts, with high propylene : ethylene ratios and high butylene yields compatible with a dimerisation–cracking mechanism. In contrast, major differences in the deactivation behaviour are demonstrated, clearly illustrating the dominant impact of the mesopore (external) surface area compared to the defect concentration or crystal morphology. Comparative evaluation in the widely studied conversion of methanol to olefins (MTO) reveals qualitatively similar trends. Quantitatively, however, a striking six-fold extension of the lifetime (347 versus 54 h) and a 3-fold higher light olefin space-time yield (6.67 versus 2.25 g C2–4= g zeolite −1 h −1 ) are observed over the best catalyst in 2M2B cracking with respect to MTO.
Catalysis Science & Technology – Royal Society of Chemistry
Published: Oct 3, 2016
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