Dry reforming of CH4 with CO2 is an effective way to convert these two greenhouse gases into useful industrial feedstock. Here, we designed and developed Ni@Y2O3 nanofibers catalyst by pyrolyzing sheet-like Ni-2(CO3) (OH)(2) grown in situ on the surface of Y2O3 nanofibers. Y2O3 nanofibers support can not only promote the contact of the reaction gas with the catalyst due to its self-supporting effect, but also improve the ability to capture CO2 because of its basic oxide properties. Meanwhile, the oxygen exchange between the catalyst and CO2 could promote the oxidation of carbon deposits, and further improve activity and stability of the catalyst. Besides, the catalyst obtained by low-temperature pyrolysis could maintain the sheet-structure of nickel on the surface of support, which is conducive to improve its catalytic activity, stability, and resistance to carbon deposition. This work has a positive effect on improving the design of catalysts as well as producing industrial chemicals and reducing the environmental pollution. (C) 2020 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.

• Journal: International Journal Of Hydrogen Energy
• Volume: 45
• Issue:
• Pages: 31494-31506
• ISSN: 0360-3199
• DOI:
• Year: 2020
• Number: 56
• Type: Journal Article