Exploring the CO2 photocatalytic evolution onto the CuO (1 1 0) surface: A combined theoretical and experimental study

A combined theoretical and experimental study was performed to elucidate the photocatalytic potential of tenorite, CuO (1 1 0) and to assess the evolution pathway of carbon dioxide (CO2) evolution pathway. The calculations were performed with density functional theory (DFT) at a DFT + U + J0 and spi...

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Bibliographic Details
Published in:Heliyon
Main Authors: O. Castro-Ocampo, J.C. Ochoa-Jaimes, Christian A. Celaya, J. González-Torres, L. González-Reyes, I. Hernández-Pérez, V. Garibay-Febles, Oscar A. Jaramillo Quintero, Jesús Muñiz, R. Suárez-Parra
Format: Article in Journal/Newspaper
Language:English
Published: Elsevier 2023
Subjects:
Photocatalysis
Solar fuels
Density functional theory
CO2 transformation
Science (General)
Q1-390
Social sciences (General)
H1-99
Carbonic acid
Online Access:https://doi.org/10.1016/j.heliyon.2023.e20134
https://doaj.org/article/760c7f3588ec4491bc2491844878798f
Description
Summary:A combined theoretical and experimental study was performed to elucidate the photocatalytic potential of tenorite, CuO (1 1 0) and to assess the evolution pathway of carbon dioxide (CO2) evolution pathway. The calculations were performed with density functional theory (DFT) at a DFT + U + J0 and spin polarized level. The CuO was experimentally synthesized and characterized with structural and optical methodologies. The band structure and density of states revealed the rise of band gaps at 1.24 and 1.03 eV with direct and indirect band gap nature, respectively. These values are in accordance with the experimental evidence at 1.28 and 0.96 eV; respectively, which were obtained by UV-Vis DRS. Such a behavior could be related to enhanced photocatalytic activity among copper oxide materials. Experimental evidence such as SEM images and work function measurements were also performed to evaluate the oxide. The redox potential suggests a catalytic character of tenorite (1 1 0) for the CO2 transformation through aldehydes (methanal) intermediate formation. Furthermore, a route through methylene glycol CH2(OH)2 was also explored with the theoretical methodology. The reaction path exhibits an immediate reduction of Image 1 into a •OH radical and an [OH]− anion, in the first step. This •OH radical attacks a double bond (C = O) of Image 2 to form bicarbonate ([Image 3]−) and subsequently, carbonic acid (Image 4). The carbonic acid reacts with other •OH radical to finally form orthocarbonic acid (Image 5).

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