Highly Active Ce- and Mg-Promoted Ni Catalysts Supported on Cellulose-Derived Carbon for Low-Temperature CO 2 Methanation
The CO 2 methanation performance of Mg- and/or Ce-promoted Ni catalysts supported on cellulose-derived carbon (CDC) was investigated. The samples, prepared by biomorphic mineralization techniques, exhibit pore distributions correlated to the particle sizes, revealing a direct effect of the metal content in the textural properties of the samples. The catalytic performance, evaluated as CO 2 conversion and CH 4 selectivity, reveals that Ce is a better promoter than Mg, reaching higher conversion values in all of the studied temperature range (150–500 °C). In the interval of 350–400 °C, Ni–Mg–Ce/... Mehr ...
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| Dokumenttyp: | Text |
| Erscheinungsdatum: | 2021 |
| Schlagwörter: | Biochemistry / Biotechnology / Ecology / Environmental Sciences not elsewhere classified / Biological Sciences not elsewhere classified / Chemical Sciences not elsewhere classified / sabatier process using / large potential stability / biomorphic mineralization techniques / studied temperature range / 4 </ sub / 2 </ sub / highly active ce / highly active / textural properties / temperature co / reaction opens / promoted catalysts / promising route / particle sizes / near 100 / metal content / maximum yield / direct effect / derived carbon / consecutive cycles / catalytic performance / better promoter |
| Sprache: | unknown |
| Permalink: | https://search.fid-benelux.de/Record/base-29243825 |
| Datenquelle: | BASE; Originalkatalog |
| Powered By: | BASE |
| Link(s) : | https://doi.org/10.1021/acs.energyfuels.1c01682.s001 |
The CO 2 methanation performance of Mg- and/or Ce-promoted Ni catalysts supported on cellulose-derived carbon (CDC) was investigated. The samples, prepared by biomorphic mineralization techniques, exhibit pore distributions correlated to the particle sizes, revealing a direct effect of the metal content in the textural properties of the samples. The catalytic performance, evaluated as CO 2 conversion and CH 4 selectivity, reveals that Ce is a better promoter than Mg, reaching higher conversion values in all of the studied temperature range (150–500 °C). In the interval of 350–400 °C, Ni–Mg–Ce/CDC attains the maximum yield to methane, 80%, reaching near 100% CH 4 selectivity. Ce-promoted catalysts were highly active at low temperatures (175 °C), achieving 54% CO 2 conversion with near 100% CH 4 selectivity. Furthermore, the large potential stability of the Ni–Mg–Ce/CDC catalyst during consecutive cycles of reaction opens a promising route for the optimization of the Sabatier process using this type of catalyst.