Journal
CATALYSIS TODAY
Volume 402, Issue -, Pages 38-44Publisher
ELSEVIER
DOI: 10.1016/j.cattod.2022.02.019
Keywords
Carbon dioxide; Hydrogenation; Nickel; Iron; Hydrotalcite; Alloy
Funding
- National Natural Science Foundation of China
- National Key Research and Development Project
- [21811530293]
- [21776007]
- [2018YFE0107400]
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This study successfully developed an efficient Ni7Fe1/Al2O3 bimetallic catalyst with outstanding low-temperature activity and stability, clarifying the effect of bimetallic synergism in CO2 methanation.
The unsatisfactory low-temperature activity of Ni based catalysts in CO2 methanation calls for further optimi-zation of catalyst design. In the present work, an efficient Ni7Fe1/Al2O3 bimetallic catalyst was derived from hydrotalcite precursors that were grown in-situ on the commercial gamma-Al2O3. The resultant Ni7Fe1/Al2O3 bime-tallic catalyst exhibited exceptional low-temperature activity, whose CO2 conversion reached 75.3% at 270 degrees C under atmospheric pressure. Moreover, the Ni7Fe1/Al2O3 catalyst remained stable at 350 degrees C for 50 h. Structural characterizations revealed that the exceptional activity over the bimetallic catalyst was closely related with the formation of NiFe alloy, which modified the electronic property, enhanced the metal reducibility and enriched the surface basic sites of Ni catalysts. The good stability on the bimetallic catalyst was mainly ascribed to the excellent coke-and sintering-resistance. This work develops an efficient methanation catalyst and clarifies the effect of bimetallic synergism in CO2 methanation.
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