We report a solution plasma process for synthesizing highly dispersed copper catalysts on ZnZrOx supports, enabling selective CO production via the reverse water-gas shift pathway. The synthesis simultaneously generates surface oxygen vacancies on the support and reduces Cu precursors, stabilizing low-valent surface Cuδ+ species (0 < δ < 2). Experimental characterization combined with density functional theory calculations shows that these sites modulate hydrogen activation to produce electrophilic Hδ+ species that preferentially stabilize *COOH intermediates while suppressing *HCOO formation, thereby directing the reaction toward CO formation. As a result, a catalyst containing 2.27 wt% Cu achieves a high CO space-time yield of 714 gCO kgcat−1 h−1 at a relatively low temperature, 300 °C. These results indicate that solution plasma synthesis is a viable strategy for tailoring meta-oxide interactions and reaction selectivity in heterogeneous catalysis.
Niu et al. (Mon,) studied this question.