Neutron scattering studies of the methanol-to-hydrocarbons reaction

The methanol-to-hydrocarbons reaction uses a zeolite catalyst (typically H-ZSM-5 or SAPO-34) to produce light olefins (mainly C-2-C-4) for chemical feedstocks and methylated benzenes for use as fuels. The reaction is a major industrial process world-wide, and consequently it has been extensively studied by a wide range of physical methods (e.g. reaction testing) and spectroscopic methods. One approach that has been used relatively little to-date is neutron scattering. Neutron methods can provide information about structure, diffusion at the microscopic scale and vibrational spectra that are not limited by selection rules, fluorescence or absorption. In this mini-review we give a short introduction to neutron scattering, then describe how neutron scattering provides insight into the Bronsted acid sites of the catalyst, then consider each of the three stages of the process; induction, steady-state and deactivation. We conclude with a perspective on how neutron scattering can further support studies of MTH chemistry.

Automated summary

The methanol-to-hydrocarbons reaction is an important industrial process that uses zeolite catalysts to produce light olefins and methylated benzenes. While it has been extensively studied using various physical and spectroscopic methods, neutron scattering has been underutilized. Neutron methods can provide unique insights into the catalyst and the different stages of the process. In this mini-review, we discuss the application of neutron scattering in studying the methanol-to-hydrocarbons reaction and its potential contributions to further research.