The role of the surface acidic/basic centers and redox sites on TiO2 in the photocatalytic CO2 reduction

dc.contributor.authorCollado, L.
dc.contributor.authorReñones, P.
dc.contributor.authorFermoso, J.
dc.contributor.authorFresno, F.
dc.contributor.authorGarrido, L.
dc.contributor.authorPérez-Dieste, V.
dc.contributor.authorEscudero, C.
dc.contributor.authorHernández-Alonso, M.
dc.contributor.authorCoronado, J.M.
dc.contributor.authorSerrano, D.P.
dc.contributor.authorde la Peña O´Shea, V.A.
dc.date.accessioned2024-02-07T08:16:24Z
dc.date.available2024-02-07T08:16:24Z
dc.date.issued2022
dc.description.abstractThe development of sustainable processes for CO2 reduction to fuels and chemicals is one of the most important challenges to provide clean energy solutions. The use of sunlight as renewable energy source is an interesting alternative to power the electron transfer required for artificial photosynthesis. Even if redox sites are mainly responsible for this process, other reactive acidic/basic centers also contribute to the overall reaction pathway. However, a full understanding of the CO2 photoreduction mechanism is still a scientific challenge. In fact, the lack of agreement on standardized comparison criteria leads to a wide distribution of reported productions, even using the same catalyst, which hinders a reliable interpretation. An additional difficulty is ascertaining the origin of carbon-containing products and effect of surface carbon residues, as well as the reaction intermediates and products under real dynamic conditions. To determine the elusive reaction mechanism, we report an interconnected strategy combining in-situ spectroscopies, theoretical studies and catalytic experiments. These studies show that CO2 photoreduction productions are influenced by the presence of carbon deposits (i.e. organic molecules, carbonates and bicarbonates) over the TiO2 surface. Most importantly, the acid/base character of the surface and the reaction medium play a key role in the selectivity and deactivation pathways. This TiO2 deactivation is mainly initiated by the formation of carbonates and peroxo- species, while activity can be partially recovered by a mild acid washing treatment. We anticipate that these findings and methodology enlighten the main shadows still covering the CO2 reduction mechanism, and, most importantly, provide essential clues for the design of emergent materials and reactions for photo(electro)catalytic energy conversion.es
dc.identifier.doi10.1016/j.apcatb.2021.120931es
dc.identifier.issn09263373
dc.identifier.urihttps://hdl.handle.net/10115/29815
dc.language.isoenges
dc.publisherElsevier B.V.es
dc.rights.accessRightsinfo:eu-repo/semantics/restrictedAccesses
dc.subjectIn-situ 13C NMRes
dc.subjectIn-situ NAP-XPSes
dc.subjectIntermediateses
dc.subjectPhotocatalytic CO2 reductiones
dc.subjectTiO2 active reaction pathwayses
dc.titleThe role of the surface acidic/basic centers and redox sites on TiO2 in the photocatalytic CO2 reductiones
dc.typeinfo:eu-repo/semantics/articlees

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