Hydrogen production from methane via liquid phase microwave plasma: A deoxidation strategy

In this paper, in order to improve hydrogen production, the effect of dissolved oxygen (DO) on methane (CH4) reforming was studied by liquid phase microwave discharge firstly. DO was reduced by deducing pressure and gas replacement, and the reaction mechanism was researched by radical detection. It was revealed that reducing DO can improve hydrogen (H2) yield and H2 selectivity and energy efficiency of hydrogen production. When microwave power was 900 W and the DO was decreased from 4.82 mg/L to 0.65 mg/L, the production and selectivity of H2 increased by 21.3 % and 22.6 % respectively, and the energy efficiency of hydrogen production increased by 33.1 %. Through the study on the characteristics of discharge radicals, it was concluded that center dot H extraction and center dot H coupling reaction and center dot OH oxidation center dot CHX are the main ways to produce hydrogen. The existence of DO affects the formation of H2 by limiting the decomposition of water molecules. In addition, the reduction of DO can improve the stability of discharge. These results indicate that reducing the DO can be a simple, effective and energy conservation method to increase the selectivity of target products in the liquid phase discharge reforming of CH4.

Automated summary

This paper investigates the influence of dissolved oxygen on methane reforming process by liquid phase microwave discharge. The results show that reducing dissolved oxygen can improve hydrogen yield, selectivity, and energy efficiency. The study also reveals the main pathways for hydrogen production, which are dot H extraction, dot H coupling reaction, and dot OH oxidation center dot CHX.