Outstanding low-temperature activity and stability of NiCo alloy catalysts derived from NiCoAl-LDHs for CO2 methanation

IF 5.6 2区工程技术 Q2 ENERGY & FUELS Journal of The Energy Institute Pub Date : 2025-03-12 DOI:10.1016/j.joei.2025.102070

Fanying Zhang , Bin Lu , Linlin Xu

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Abstract

Compared with monometallic catalysts, alloy catalysts demonstrate inferior catalytic advantages because of the synergistic promotion effect of bimetal. Here, we prepared NiCo alloy catalysts using NiCoAl-LDHs as precursors by thermal method and used them for the CO₂ methanation reaction. The Ni₇Co₃-R alloy catalyst exhibits outstanding low-temperature catalytic activity (200–300 °C) in the CO₂ methanation reaction, and has not been deactivated at 300 °C for 180 h. The synergistic effect of Ni and Co in the alloy catalysts is beneficial to reduce the particle size, promote the reduction of the catalysts and increase the number of moderately basic sites, which are beneficial to the adsorption of CO₂ and the formation of CH₄. Further, the hydrotalcite-derived NiCo alloy catalysts have a unique mosaic structure, thereby significantly improving the stability of catalysts. The in-situ FTIR analysis confirm the CO₂ methanation reaction via the CO∗ pathway over Ni₇Co₃Al-R catalyst. This work has a certain guiding effect on the preparation of Ni-base catalysts with excellent low-temperature activity and high stability.

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来源期刊

Journal of The Energy Institute 工程技术-能源与燃料

CiteScore

10.60

自引率

5.30%

发文量

166

审稿时长

16 days

期刊介绍： The Journal of the Energy Institute provides peer reviewed coverage of original high quality research on energy, engineering and technology.The coverage is broad and the main areas of interest include: Combustion engineering and associated technologies; process heating; power generation; engines and propulsion; emissions and environmental pollution control; clean coal technologies; carbon abatement technologies Emissions and environmental pollution control; safety and hazards; Clean coal technologies; carbon abatement technologies, including carbon capture and storage, CCS; Petroleum engineering and fuel quality, including storage and transport Alternative energy sources; biomass utilisation and biomass conversion technologies; energy from waste, incineration and recycling Energy conversion, energy recovery and energy efficiency; space heating, fuel cells, heat pumps and cooling systems Energy storage The journal''s coverage reflects changes in energy technology that result from the transition to more efficient energy production and end use together with reduced carbon emission.