Optimizing Materials to Boost the Valorization of CO2: Tuning Cobalt–Cobalt Interactions on In2O3‑Based Photothermal Catalysts

The valorization of CO2 is an important challenge within the current panorama, since this molecule is probably the main contributor to climate change. In this study, the synthesis of materials based on a nanostructured batonnet-type indium oxide is carried out. In them, different amounts of Co are i...

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Veröffentlicht in:	ACS applied materials & interfaces 2024-11, Vol.16 (45), p.62131-62141
Hauptverfasser:	Sayago-Carro, Rocío, Barba-Nieto, Irene, Gómez-Cerezo, Natividad, Rodriguez, José A., Fernández-García, Marcos, Kubacka, Anna
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Sprache:	eng
Schlagworte:	carbon dioxide carbon monoxide catalytic activity climate change CO2 elimination and valorization cobalt composite catalysts Energy, Environmental, and Catalysis Applications indium indium oxide MATERIALS SCIENCE photothermal reaction single atom Co species species structure-activity relationships subnanometric Co clusters X-ray absorption spectroscopy
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creator	Sayago-Carro, Rocío Barba-Nieto, Irene Gómez-Cerezo, Natividad Rodriguez, José A. Fernández-García, Marcos Kubacka, Anna
description	The valorization of CO2 is an important challenge within the current panorama, since this molecule is probably the main contributor to climate change. In this study, the synthesis of materials based on a nanostructured batonnet-type indium oxide is carried out. In them, different amounts of Co are introduced, varying between 2 and 8% mol. It is verified that the most active sample in the transformation of carbon dioxide to carbon monoxide contains 6 mol %. of Co. This sample’s activity under dual excitation exceeds the thermal counterpart by more than 30%. After carrying out a complete physical and chemical characterization with the help of X-ray absorption spectroscopy and other techniques, it is shown that catalysts with amounts of cobalt equal to or below 4 mol % contain isolated single-atom species, while those with higher amounts of metal display a Co–Co interaction which triggers the evolution of the samples under reaction conditions. The optimum control of this Co–Co interaction and the nature of the final cobalt-containing species determine dual photothermal catalytic properties. This work establishes a structure–activity relationship to interpret the catalytic behavior of highly dispersed subnanometric cobalt species, and thus an avenue to optimize the photothermal valorization of carbon dioxide.
doi_str_mv	10.1021/acsami.4c14280
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The optimum control of this Co–Co interaction and the nature of the final cobalt-containing species determine dual photothermal catalytic properties. 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subjects	carbon dioxide carbon monoxide catalytic activity climate change CO2 elimination and valorization cobalt composite catalysts Energy, Environmental, and Catalysis Applications indium indium oxide MATERIALS SCIENCE photothermal reaction single atom Co species species structure-activity relationships subnanometric Co clusters X-ray absorption spectroscopy
title	Optimizing Materials to Boost the Valorization of CO2: Tuning Cobalt–Cobalt Interactions on In2O3‑Based Photothermal Catalysts
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