Consequence of products from oxidative coupling of methane in a non-oxidative high temperature environment

Oxidative coupling of methane (OCM) is a direct process that converts methane to higher hydrocarbons, such as ethylene. For several decades, various catalysts and their reaction mechanisms have been investigated to obtain high selectivity for the target products. However, the consequences of OCM products after O-2 depletion at high temperatures, which is generated by an exothermic reaction, have been often overlooked. In the present study, a two-stage reactor that mimics an industrial reactor was used to study the successive reactions of OCM products. Gas phase homogeneous and heterogeneous reactions on the surface of catalysts and supports have been systematically investigated. Dehydrogenation of OCM products to acetylene and the following condensation occurs in the gas phase. Meanwhile, steam reforming of OCM products concurrently followed by water gas shift reactions was observed on various catalysts and supports and led to the loss of C-2 yield. Based on the investigations, a design guideline for the OCM reactor is proposed.

Automated summary

In this study, a two-stage reactor was used to investigate the successive reactions of oxidative coupling of methane (OCM) products. Homogeneous and heterogeneous gas phase reactions of OCM products on catalysts and supports were systematically investigated. Dehydrogenation and condensation of OCM products were observed in the gas phase, while steam reforming and water gas shift reactions led to the loss of C-2 yield. A design guideline for OCM reactors was proposed based on the findings.