Photoelectrocatalytic characterization of carbon-doped NaTaO3 applied in the photoreduction of CO2 towards the formaldehyde production

Photoelectrocatalytic characterization of carbon-doped NaTaO3 applied in the photoreduction of CO2 towards the formaldehyde production

[Display omitted] •Carbon-doped NaTaO3 was prepared by a solvo-combustion method to produce formaldehyde from CO2.•Band gap size of NaTaO3 was modified by the effect of carbon-doping.•NaTaO3-C 650 °C showed both, an optimal crystallinity and active surface ratio.•Carbon-doping enhances the electrica...

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Bibliographic Details
Published in:Journal of CO2 utilization Vol. 27; pp. 179 - 187
Main Authors: Mora-Hernandez, J.M., Huerta-Flores, Ali M., Torres-Martínez, Leticia M.
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-10-2018
Subjects:
Carbon-doped perovskites
CO2 photoreduction
Solar-based fuels
CO2 photoreduction
Solar-based fuels
Carbon-doped perovskites
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Summary:[Display omitted] •Carbon-doped NaTaO3 was prepared by a solvo-combustion method to produce formaldehyde from CO2.•Band gap size of NaTaO3 was modified by the effect of carbon-doping.•NaTaO3-C 650 °C showed both, an optimal crystallinity and active surface ratio.•Carbon-doping enhances the electrical conductivity of NaTaO3.•The presence of the second phase Na2Ta4O11 improves the CO2 photoreduction. A carbon-doped NaTaO3 perovskite (NaTaO3-C) was synthesized by the chemical solvo-combustion method. The as-prepared material NaTaO3-C was annealed at temperatures of 500, 550, 600, 650, and 700 °C in an air atmosphere, in order to study the crystalline phases present in these samples, and to relate the morphological, physical and chemical properties of the carbon-doped perovskites to the photocatalytic activity to perform the CO2 reduction in aqueous medium. The formation of a composite between the carbon and the perovskite, and the presence of a second phase, Na2Ta4O11, was confirmed through XRD measurements. While it is true that both formations improved the photocatalytic activity of the NaTaO3-C, an optimal carbon amount is a key parameter to reduce the band gap value and diminish the charge transference resistance by an improvement in the electrical conductivity of the sample. It is worth to mention that the optimal ratio between the surface area and crystallinity of the sample was achieved by the NaTaO3-C annealed al 650 °C. These parameters play an important role to explain an improved photocatalytic activity caused by a higher reactive surface and lower recombination of the charges photogenerated onto larger crystals. The photoelectrochemical tests revealed that the material annealed a 650 °C is the only sample with a conduction band value more negative than the potential required to perform the generation of formaldehyde from the photocatalytic reduction of CO2. The photocatalytic activity was evaluated in neutral aqueous medium, NaTaO3-C 650 °C presented the highest formaldehyde production (39 μmol  g−1).
ISSN:2212-9820
2212-9839
DOI:10.1016/j.jcou.2018.07.014