Abstract
Carbon dioxide capture and use as a carbon feedstock presents both environmental and industrial benefits. Here we report the discovery of a hybrid oxide catalyst comprising manganese oxide nanoparticles supported on mesoporous spinel cobalt oxide, which catalyses the conversion of carbon dioxide to methanol at high yields. In addition, carbon-carbon bond formation is observed through the production of ethylene. We document the existence of an active interface between cobalt oxide surface layers and manganese oxide nanoparticles by using X-ray absorption spectroscopy and electron energy-loss spectroscopy in the scanning transmission electron microscopy mode. Through control experiments, we find that the catalyst's chemical nature and architecture are the key factors in enabling the enhanced methanol synthesis and ethylene production. To demonstrate the industrial applicability, the catalyst is also run under high conversion regimes, showing its potential as a substitute for current methanol synthesis technologies.
Highlights
Carbon dioxide capture and use as a carbon feedstock presents both environmental and industrial benefits
We report a highly active and highly selective hybrid oxide catalyst composed of manganese oxide nanoparticles (NPs) supported on a mesoporous cobalt oxide support for the production of methanol under mild pressure and temperature conditions
The turnover frequency (TOF) of this catalyst compared with the support alone (m-Co3O4) or the MnOx NPs supported on mesoporous SiO2 (m-SiO2) is 3 and 25 times higher, respectively
Summary
Carbon dioxide capture and use as a carbon feedstock presents both environmental and industrial benefits. We report the discovery of a hybrid oxide catalyst comprising manganese oxide nanoparticles supported on mesoporous spinel cobalt oxide, which catalyses the conversion of carbon dioxide to methanol at high yields. To demonstrate the industrial applicability, the catalyst is run under high conversion regimes, showing its potential as a substitute for current methanol synthesis technologies. Carbon dioxide is a harmful greenhouse gas produced in large quantities as a by-product in many industrial processes and in the generation of electricity[1]. It is an transportable fuel; fuel cell technology already exists (direct methanol fuel cells); and it can be used as a precursor for many valuable chemical intermediates. Even nonmetal Lewis pairs have been successfully implemented as phase-transfer catalysts to solubilize and reduce CO2 (refs 14,15)
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