Author:

Keywords:

CARBON-DIOXIDE, CO2 METHANATION, EARTH, Energy & Fuels, Engineering, Engineering, Chemical, GAS SHIFT REACTION, HYDROGENATION, NI/AL2O3 CATALYSTS, NI/ZRO2 CATALYST, PERFORMANCE, Science & Technology, SUPPORTED NICKEL-CATALYSTS, SURFACE, Technology, 0306 Physical Chemistry (incl. Structural), 0904 Chemical Engineering, 0914 Resources Engineering and Extractive Metallurgy, Energy, 4004 Chemical engineering, 4019 Resources engineering and extractive metallurgy

Abstract:

Reverse water gas shift (RWGS) competes with methanation as a direct pathway in the CO2 recycling route, with methanation being a dominant process in the low-temperature window and RWGS at higher temperatures. This work showcases the design of multi-component catalysts for a full-temperature-range RWGS behavior by suppressing the methanation reaction at low temperatures. The addition of alkali promoters (Na, K, and Cs) to the reference Ni/CeO2 catalyst allows identifying a clear trend in RWGS activation promotion in both low- and high-temperature ranges. Our characterization data evidence changes in the electronic, structural, and textural properties of the reference catalyst when promoted with selected dopants. Such modifications are crucial to displaying an advanced RWGS performance. Among the studied promoters, Cs leads to a more substantial impact on the catalytic activity. Beyond the improved CO selectivity, our best performing catalyst maintains high conversion levels for long-term runs in cyclable temperature ranges, showcasing the versatility of this catalyst for different operating conditions. All in all, this work provides an illustrative example of the impact of promoters on fine-tuning the selectivity of a CO2 conversion process, opening new opportunities for CO2 utilization strategies enabled by multi-component catalysts.