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Volcano-Shaped Correlation Dictated Superior Activity for Ultralow Al-Doped Iron Oxide toward High-Temperature Water–Gas Shift Reaction

Binbin Qian, Yan Xue, Sasha Yang, Jianghao Zhang, Cheng Liu, Zongtang Liu, Zhenghao Fei, Baiqian Dai, Jefferson Zhe Liu, Yong Wang, Lian Zhang

2024ACS Catalysis18 citationsDOI

Abstract

Earth-abundant iron oxide is an important catalyst for the production of hydrogen via a broad range of catalytic reactions, including the high-temperature water–gas shift reaction (HT-WGSR). For iron oxide catalysts, the aluminum (Al) dopant, with a relatively large concentration of ∼5 wt %, is commonly considered as a textural promoter to stabilize the active phase magnetite. However, the role of Al and its underlying mechanisms are yet to be fully understood. Here, we report the discovery of a volcano-shaped correlation between the Al doping amount and catalyst activity and, potentially, an extremely low yet optimum content of ∼0.85 wt % for Al. Such a low-content Al is initially highly dispersed within iron oxide, exerting a negligible effect on the catalyst structure. However, it can undertake in situ transformation into a Fe 3 O 4 @Fe(Fe 1– x,Al x ) 2 O 4 core–shell structure during H 2 reduction. The resultant catalyst outperforms pure magnetite (Al-free) and those with larger Al contents, enabling the achievement of the thermodynamic limit of 76–80% CO conversion at 425–450 °C and a low apparent activation energy of ∼41 kJ/mol compared to its high-Al counterparts. Advanced in situ and ex situ characterizations, along with density functional theory (DFT) calculations, confirmed a preferential diffusion of Al on the catalyst surface/shell, occupying the octahedral Fe sites of magnetite which are in turn highly activated in moderating the adsorption of CO and simultaneously alleviating the hydrogen-binding energy for a spontaneous H 2 O dissociation. In contrast, for the high-Al content such as 1.72 wt %, phase segregation for the formation of discrete alumina occurs on the surface, exerting strong adsorption of CO but weak adsorption of H 2 O at temperatures >400 °C. This in turn poisons and deactivates the catalyst quickly. By precisely controlling the amount of a dopant such as Al on the atomic level, the activity of the iron oxide-based catalysts can be unlocked in achieving maximal performance.

Topics & Concepts

CatalysisWater-gas shift reactionMagnetiteDopantIron oxideOxideHydrogenChemistryAdsorptionInorganic chemistryDissociation (chemistry)Chemical engineeringActivation energyMaterials scienceDopingPhysical chemistryMetallurgyOrganic chemistryBiochemistryEngineeringOptoelectronicsIron oxide chemistry and applicationsMinerals Flotation and Separation TechniquesCatalysts for Methane Reforming