TY - JOUR
T1 - Dry methane reforming over lanthanide-doped Co-Al catalysts prepared via a solution combustion method
AU - Shoganbek, Dinmukhamed
AU - Martinez-Klimov, Mark
AU - Yevdokimova, Olha
AU - Peuronen, Anssi
AU - Lastusaari, Mika
AU - Aho, Atte
AU - Tungatarova, Svetlana A.
AU - Baizhumanova, Tolkyn S.
AU - Zhumadullaev, Daulet A.
AU - Zhumabek, Manapkhan
AU - Aubakirov, Yermek A.
AU - Manabayeva, Alua
AU - Mäki-Arvela, Päivi
AU - Murzin, Dmitry Yu.
PY - 2025/2/7
Y1 - 2025/2/7
N2 - Cobalt-based catalysts containing Ce, La and Al were prepared via solution combustion synthesis (SCS) and used in dry reforming of methane (DRM). Combustion temperature for the highest active 20Co–10La–20Al catalyst measured during the combustion process was 861 1C, explaining the formation of CoAl
2O
4, which was active for DRM in the present work. No graphite structure was defined from the XRD pattern and TPO profiles of the spent Co–La–Al catalyst, while other catalysts contained this phase. In addition, only 10 wt% of carbon was identified in Co–La–Al, according to CHNS results. All catalysts were well dispersed, and the metal particle size varied between 19 and 28 nm. TPR analyses showed that doping of rare-earth metals leads to easier reduction due to oxygen vacancies, which suppress coking. The highest CH
4 transformation rate and space-time yield of hydrogen were observed for CoLaAl, which exhibited a metal particle size of 23 nm, giving the lowest carbon content in the spent catalysts after temperature cycling experiments in DRM. This catalyst containing metallic cobalt and an active CoAl
2O
4 spinel demonstrated stable formation of hydrogen and CO during 50 h time-on-stream. The spinel phase was, however, decomposed during the DRM. The best catalyst also contained a perovskite-type mixed oxide, LaCo
xAl
1–xO
3, which was already formed during synthesis through an SCS method. This phase was not, however, stable in long-term experiments.
AB - Cobalt-based catalysts containing Ce, La and Al were prepared via solution combustion synthesis (SCS) and used in dry reforming of methane (DRM). Combustion temperature for the highest active 20Co–10La–20Al catalyst measured during the combustion process was 861 1C, explaining the formation of CoAl
2O
4, which was active for DRM in the present work. No graphite structure was defined from the XRD pattern and TPO profiles of the spent Co–La–Al catalyst, while other catalysts contained this phase. In addition, only 10 wt% of carbon was identified in Co–La–Al, according to CHNS results. All catalysts were well dispersed, and the metal particle size varied between 19 and 28 nm. TPR analyses showed that doping of rare-earth metals leads to easier reduction due to oxygen vacancies, which suppress coking. The highest CH
4 transformation rate and space-time yield of hydrogen were observed for CoLaAl, which exhibited a metal particle size of 23 nm, giving the lowest carbon content in the spent catalysts after temperature cycling experiments in DRM. This catalyst containing metallic cobalt and an active CoAl
2O
4 spinel demonstrated stable formation of hydrogen and CO during 50 h time-on-stream. The spinel phase was, however, decomposed during the DRM. The best catalyst also contained a perovskite-type mixed oxide, LaCo
xAl
1–xO
3, which was already formed during synthesis through an SCS method. This phase was not, however, stable in long-term experiments.
UR - https://www.webofscience.com/api/gateway?GWVersion=2&SrcApp=aboakademi&SrcAuth=WosAPI&KeyUT=WOS:001396716200001&DestLinkType=FullRecord&DestApp=WOS_CPL
U2 - 10.1039/d4ma00991f
DO - 10.1039/d4ma00991f
M3 - Article
SN - 2633-5409
VL - 6
SP - 1173
EP - 1190
JO - Materials Advances
JF - Materials Advances
IS - 3
ER -