Tailored mesoporosity and acidity of shape-selective fibrous silica beta zeolite for enhanced toluene co-reaction with methanol

Tailored mesoporosity and acidity of shape-selective fibrous silica beta zeolite for enhanced toluene co-reaction with methanol

[Display omitted] •Decreasing the urea/TEOS ratio reduces the mesoporosity and acidity of FSB.•Denser silica dendrimers improve the p-xylene selectivity and yield.•1:1-FSB exhibited a fivefold increased p-xylene yield at 673 K.•Denser FSBs increased the internal mass diffusion resistance and activat...

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Bibliographic Details
Published in:Chemical engineering science Vol. 193; pp. 217 - 229
Main Authors: Ghani, N.N.M., Jalil, A.A., Triwahyono, S., Aziz, M.A.A., Rahman, A.F.A., Hamid, M.Y.S., Izan, S.M., Nawawi, M.G.M.
Format: Journal Article
Language:English
Published: Elsevier Ltd 16-01-2019
Subjects:
Fibrous silica beta
Mesoporosity: acidity
Shape-selective toluene methylation
Urea/TEOS ratio
Mesoporosity: acidity
Shape-selective toluene methylation
Fibrous silica beta
Urea/TEOS ratio
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Summary:[Display omitted] •Decreasing the urea/TEOS ratio reduces the mesoporosity and acidity of FSB.•Denser silica dendrimers improve the p-xylene selectivity and yield.•1:1-FSB exhibited a fivefold increased p-xylene yield at 673 K.•Denser FSBs increased the internal mass diffusion resistance and activation energy.•p-xylene yield was highly affected by reactant molar ratio and reaction temperature. Fibrous silica beta zeolite (FSB) catalysts, which are excellent catalytic materials for petrochemical processes, were prepared by a microemulsion system assisted by commercial beta zeolite (BEA) seed crystallization under different urea/tetraethyl orthosilicate (urea/TEOS) ratios, denoted as 0.5:1-FSB, 1:1-FSB and 1:0.5-FSB. The physicochemical properties of the catalysts were investigated by XRD, MP-AES, FESEM, TEM, N2 physisorption and FTIR. The characterization results revealed that the dendrimeric silica fibers surrounding the BEA core shell of FSB were improved when the urea/TEOS ratio was altered, particularly for the ratio of 1:1. The highest terminal silanol and silanol nest intensities further confirmed its highest density of dendrimeric fibers. The catalytic testing of toluene methylation at 673 K resulted in the following order of p-, o- and m-xylene production ratio: 1:1-FSB (6/2/0) > 0.5:1-FSB (6/4/4) > 1:0.5-FSB (2/1/1). The catalyst with denser dendrimeric fibers led to lower acidity and pore volumes, which assist in selectively producing p-xylene and limiting the formation of side products. The FSB with denser dendrimeric fibers was also found to have a slower internal mass transfer rate, which is directly proportional to the activation energy. Optimization by the response surface methodology showed that the reactant molar ratio and reaction temperature were significant factors in the toluene methylation. The remarkable performance of these catalysts in the toluene co-reaction with methanol highlights their potential as future catalysts in the industrial application of toluene methylation and other chemical processes.
ISSN:0009-2509
1873-4405
DOI:10.1016/j.ces.2018.09.009