posted on 2021-09-23, 12:35authored byLei He, Mingrun Li, Wen-Cui Li, Wei Xu, Yang Wang, Yan-Bo Wang, Wenjie Shen, An-Hui Lu
Methane dry reforming,
co-converting
greenhouse gases CH4 and CO2 into chemically
active syngas (H2/CO), affords a promising route for producing
chemicals and fuels from carbon resources. Ni catalysts are the most
active for this reaction but suffer from the dilemma of rapid deactivation
caused by metal sintering at higher temperatures (>973 K) or coke
accumulation at relatively lower temperatures (673–973 K).
Here, we report a catalyst configurationNi particles (15 nm)
confined by a 1–2 nm-thick multielement-oxide (MEO) layerallows
a stable operation at 873–1073 K with a stoichiometric CH4/CO2 ratio of 1.0, that is, the severe conditions
for catalyst deactivation but of industrial interest for process efficiency
and atomic economy. The in situ-evolved MEO layer resembles the property
of high-entropy oxide, which stabilizes the Ni particles with appropriate
size and high-index facets, even at 1173 K. Meanwhile, in situ TEM
under near atmospheric pressure combining intelligent gravity analysis
(IGA)-mass spectrometry (MS) characterizations prove that this unique
structure balanced the activation of CH4 and CO2. Thus, the lifetime of the catalyst has been efficiently prolonged
with nearly coke-free operations, even at 873 K, the most severe coking
temperature. This high-entropy design and stabilization effect offers
a facile strategy to precisely fabricate active and robust metal catalysts
with wide operation temperatures for many challenging reactions.