Methanol to hydrocarbons conversion: Why dienes and monoenes contribute differently to catalyst deactivation?

[Display omitted] •Dienes and formaldehyde are key intermediates in causing deactivation during MTH.•Distinct intermediates are formed during HCHO-monoenes and HCHO-dienes reactions.•Distinct rate constants quantify proton transfer and desorption of intermediates.•Mixed-effects model describes trans...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2022-06, Vol.437, p.134229, Article 134229
Main Authors: Shi, Zhichen, Arora, Sukaran S., Trahan, Daniel W., Hickman, Daniel, Bhan, Aditya
Format: Article
Language:English
Subjects:
Bayesian Statistics
Chemical transients
Deactivation
Methanol-to-hydrocarbons
Mixed-effects kinetic model
Reaction kinetics
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Summary:[Display omitted] •Dienes and formaldehyde are key intermediates in causing deactivation during MTH.•Distinct intermediates are formed during HCHO-monoenes and HCHO-dienes reactions.•Distinct rate constants quantify proton transfer and desorption of intermediates.•Mixed-effects model describes transient rates with minimal correlation in residuals. Dienes, formed at much lower concentrations than monoenes via alkylation of monoenes with formaldehyde (HCHO), have much higher propensity than monoenes to foment catalyst deactivation in methanol-to-hydrocarbons (MTH) conversion over zeolites via HCHO-mediated deactivation pathways. The mechanistic basis for why monoenes and dienes contribute differently to cause catalyst deactivation during MTH is investigated using independent kinetic studies of HCHO reactions with representative monoenes and dienes, i.e., propylene and 1,3-butadiene, over zeolites. Despite 3,6-dihydro-2H-pyran being the predominant product for both propylene/HCHO and 1,3-butadiene/HCHO reactions, a combination of transient and steady-state rate measurements and stoichiometric experiments reveals distinct persistent intermediates being involved in the addition of HCHO to different surface-bound alkyl species derived from propylene and butadiene. These persistent intermediates desorb only via HCHO- and water-mediated proton transfer steps and as such can be sequestered on the catalyst. A nonlinear mixed-effects kinetic model reveals that the intermediate formed during HCHO-diene reactions has a higher steady-state surface coverage and its desorption via HCHO- and water-mediated routes exhibit > 8× and > 3×, respectively, higher rate constants than those during HCHO-monoene reactions. These results evidence the distinct identity, surface coverage, and reactivities of surface-bound alkyl intermediates as critical factors in the much more pernicious effects of dienes compared to monoenes on catalyst lifetime during MTH.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2021.134229