Abstract
Methane dehydroaromatization reaction at 700 degrees C over Mo/ZSM-5 involves numerous modifications of the molybdenum species from the catalyst preparation and throughout the catalyst lifetime, composed of 4 successive steps: calcination, activation, induction, and deactivation. A thorough kinetic study was undertaken with the aim to understand the transformation phenomena occurring on the catalyst during each stage of the reaction, using methane gas hourly space velocity per gram of catalyst (M-GHSV) from 1 to 29 L-CH4 h(-1) g(cat)(-1). Here from, unexpected behaviors were observed, supported by molecular modeling results. MoO3 firstly reacts stoichiometrically during the calcination (Delta rH=0.86 eV) with bridged hydroxyl pairs yielding [Mo2O5](2+) species (calcination). Thereafter, [Mo2O5](2+) slowly reduces by methane to form [Mo2C2](2+) (activation). The latter converts methane to ethylene (E-A = 1.49 eV), which dimerizes two times faster to butene through hydrocarbon pool catalysis rather than through Bronsted acid sites (induction). The catalyst deactivates through an inhibition effect of aromatics, which adsorb strongly onto [Mo2C2](2+) (Delta H-ads similar to 0.7 eV) (deactivation). The large amount of autogenous hydrogen produced at lower space velocity allows preventing the active species poisoning, leading to slower deactivation rate.
NSTL
Elsevier