Oxygen vacancies in Ru/TiO 2 - drivers of low-temperature CO 2 methanation assessed by multimodal operando spectroscopy

Hydrogenation of CO is very attractive for transforming this greenhouse gas into valuable high energy density compounds. In this work, we developed a highly active and stable Ru/TiO catalyst for CO methanation prepared by a solgel method that revealed much higher activity in methanation of CO (ca. 4...

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Published in:iScience 2022-03, Vol.25 (3), p.103886
Main Authors: Cisneros, Sebastian, Abdel-Mageed, Ali, Mosrati, Jawaher, Bartling, Stephan, Rockstroh, Nils, Atia, Hanan, Abed, Hayder, Rabeah, Jabor, Brückner, Angelika
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creator Cisneros, Sebastian
Abdel-Mageed, Ali
Mosrati, Jawaher
Bartling, Stephan
Rockstroh, Nils
Atia, Hanan
Abed, Hayder
Rabeah, Jabor
Brückner, Angelika
description Hydrogenation of CO is very attractive for transforming this greenhouse gas into valuable high energy density compounds. In this work, we developed a highly active and stable Ru/TiO catalyst for CO methanation prepared by a solgel method that revealed much higher activity in methanation of CO (ca. 4-14 times higher turnover frequencies at 140-210°C) than state-of-the-art Ru/TiO catalysts and a control sample prepared by wetness impregnation. This is attributed to a high concentration of O-vacancies, inherent to the solgel methodology, which play a dual role for 1) activation of CO and 2) transfer of electrons to interfacial Ru sites as evident from operando DRIFTS and EPR investigations. These results suggest that charge transfer from O-vacancies to interfacial Ru sites and subsequent electron donation from filled metal d-orbitals to antibonding orbitals of adsorbed CO are decisive factors in boosting the CO methanation activity.
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title Oxygen vacancies in Ru/TiO 2 - drivers of low-temperature CO 2 methanation assessed by multimodal operando spectroscopy
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