Electrically Assisted Low-Temperature Dry Reforming of Methane Suppressing Carbon Deposition under High-Pressure Conditions

Our approach to high-pressure dry reforming of methane (DRM) achieves synergistic performance enhancement via application of an electric field (EF) over a 1 wt % Ru/La₂Ce₂O₇ (LCO) catalyst. Conventional DRM is adversely affected by compromised activity and catalyst stability under pressurization caused by unfavorable thermodynamics. In sharp contrast, EF-assisted DRM has achieved exceptional CH₄/CO₂ conversion. In fact, high H₂/CO ratios show coke resistance at temperatures as low as 473 K, which exceeds the equilibrium conversion constraints observed for conventional DRM. Pressurization was found to further enhance EF-assisted DRM activity by increasing the surface coverage of adsorbates that facilitates surface protonics, which is a proton hopping mechanism that promotes CH₄ dissociative adsorption at low temperatures. Raman measurements and TEM-EDX mapping results show remarkable suppression of carbon deposition and metal sintering as the cause of long-term durability of EF-assisted DRM. When elucidating the reaction mechanism, temperature dependence, and turnover frequency (TOF) investigations have indicated unconventional anti-Arrhenius behavior, particularly identifying the metal–support interface as the primary active site. Partial pressure-based kinetic studies and transient gas-switch test results suggest that CH_xO species serve as key reaction intermediates capable of direct decomposition into H₂ and CO. NNP-based structural optimization calculations identified CHO* as the most stable intermediate species formed through lattice oxygen interactions with CH₄ dissociation. From C–H*, although oxidation into CHO* is kinetically favorable, dehydrogenation into C* is thermodynamically favorable. For rationalizing the distinct coke suppression shown by EF-assisted DRM, investigations of C–C* aggregation have revealed that C–H* formation grew increasingly more favorable over C–C* in the presence of high surface H concentrations. Granted that high H surface coverage was found in pressurized EF-assisted DRM, this growth indicates a potential H feedback mechanism that facilitates hydrogenation to C–H*, thereby suppressing coke formation.