Formaldehyde is an important intermediate that affects the catalyst performance in the
methanol-to-hydrocarbons (MTH) conversion. In this study, photoelectron photoion …

Formaldehyde productivity and reactivity over zeolite catalysts are suggested to influence
their selectivity and stability in the methanol-to-hydrocarbons (MTH) conversion. However …

Consumer demand for environmentally friendly products, government mandates and
incentives have been driving the development of innovative solutions to produce fuels and …

The zeolite‐catalyzed methanol‐to‐aromatics (MTA) process is a promising avenue for
industrial decarbonization. This process predominantly utilizes 3‐dimensional 10‐member …

Coke-induced catalyst deactivation is one of the major challenges in commercial methanol-
to-hydrocarbon (MTH) conversion processes. It is suspected to be critically dependent on …

The development of stable and selective ZSM-5 catalysts for methanol aromatization
remains an ongoing challenge. Here, we demonstrate highly stable aromatization on ZSM-5 …

Understanding the mechanistic intricacies of hydrothermally treated zeolite is crucial for
valorizing any oxygen‐containing renewable feedstocks (eg, methanol, carbon dioxide …

Purposive regulation of the spatial location and distribution of acid sites in a zeolite catalyst,
though still rather challenging, has proved to be an effective measure to enhance its …

Regulating favorable assemblies of metallic atoms in the liquid state provides promise for
catalyzing various chemical reactions. Expanding the selection of metallic solvents …

This work presents a dual cycle-based kinetic model that uses H-ZSM-5 catalyst acidity
descriptors for the methanol-to-hydrocarbons (MTH,-olefins, MTO, and–aromatics, MTA) …