The development of high-performance copper (Cu)-based catalysts is critical to achieve the
industrial hydrogenation of dimethyl oxalate (DMO) to methyl glycolate (MG). To understand …

The semihydrogenation of dimethyl oxalate (DMO) into methyl glycolate (MG) has garnered
increasing attention in the production of the biodegradable polymer material, polyglycolic …

Copper-containing mesoporous HMS catalysts prepared via a one-pot synthesis method
based on sol− gel chemistry have been systematically characterized focusing on the effect of …

The chemoselective synthesis of ethylene glycol (EG) from the hydrogenation of dimethyl
oxalate (DMO) derived from syngas is an attractive technology in the modern chemical …

The influence of Cu loading on the structural evolution and catalytic behavior in selective
hydrogenation of dimethyl oxalate (DMO) by Mg2+ doped nanoscaled Cu–Mg/ZnO catalysts …

Partial hydrogenation of dimethyl oxalate (DMO) has attained increasing attention in the
chemical industry, which is driven by the desire to develop a means of achieving methyl …

A promising route for producing biodegradable polyglycolic acid material from syngas has
garnered increasing attentions. In this route, one of the pivotal issues is developing …

What should people do with the huge amount of CO2 captured? CO2 to CO is a promising
way for using carbon resources because CO is one component of syngas for the production …

The kinetics of dimethyl oxalate (DMO) hydrogenation over Cu (111) and Cu2O (111) has
been studied to understand the role of Cu0 and Cu+ sites in ethyl glycol (EG) production …

Mg2+ doped nanoscale Cu–Mg/ZnO catalysts prepared by the co-precipitation method have
been systematically characterized focusing on the amount of Mg2+ ions incorporated. The …