Converting CO<sub>2</sub> to CO via a Plasma-Catalyst Coupled Pathway with Ultrahigh Single-Pass CO<sub>2</sub> Conversion and ∼100% CO Selectivity
Yuran Yang, Lin Guo, Shijian Luo, Yongduo Liu, Yang Song, Hao Chen, Daojun Long, Siguo Chen, Zidong Wei
Abstract
The plasma-catalytic conversion of CO 2 to CO through reverse water gas shift (RWGS) reactions offers an appealing route for storing intermittent renewable electricity and incorporating the “3Rs” (i.e., reduce, reuse and recycle) concept for CO 2 mitigation and utilization, but the lack of efficient catalysts matched to the plasma environment has hindered the widespread deployment of this technology. Here, we report that OV–In 2 O 3 catalysts with abundant oxygen vacancies (OV) can perfectly couple to the RWGS reaction under plasma conditions via a H radical-dominated gas-phase mechanism. In this mechanism, gas-phase H radicals generated by synergistic promotion of oxygen vacancies and plasma achieved highly efficient CO 2 activation in the gas phase (plasma), which preventing CO 2 activation from the energy-intensive CO 2 adsorption-dissociation mechanism, thus significantly improves the efficiency of CO production. With this strategy, plasma–OV-In 2 O 3 shows an ultrahigh single-pass CO 2 conversion of 60.8% with ∼100% CO selectivity under ambient conditions. This study delves deeply into the plasma-catalytic CO 2 activation process and proposes a H radical-dominated gas-phase mechanism for CO 2 -to-CO conversion, offering a pathway for seamlessly integrating CO 2 mitigation with energy storage and value-added chemical product synthesis.