Photothermal Catalytic CO2 Conversion: Beyond Catalysis and Photocatalysis

Fresno, Fernando; Iglesias‐Juez, Ana; Coronado, Juan M.

doi:10.1007/s41061-023-00430-z

Cited by 20 publications

(3 citation statements)

References 118 publications

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“…Though there are several reports on the synthesis and characterization of cementite, optical absorption studies on cementite is rare. Fresno et al reported a UV–vis absorption spectrum for Fe 3 C quite similar to the present one. For nitrogen-doped Fe 3 C, Yang et al estimated the direct band gap energy of 1.65 eV from UV–vis absorption spectra.…”

Section: Resultsmentioning

confidence: 99%

Reaction Atmosphere-Controlled Thermal Conversion of Ferrocene to Hematite and Cementite Nanomaterials─Structural and Spectroscopic Investigations

Kundu,

Sarkar,

Ghorai

et al. 2024

ACS Omega

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Recently, we have reported the influence of various reaction atmospheres on the solid-state reaction kinetics of ferrocene, where oxalic acid dihydrate was used as a coprecursor. In this light, present study discusses on the nature of decomposed materials of the solid-state reactions of ferrocene in O 2 , air, and N 2 atmospheres. The ambient and oxidative atmospheres caused the decomposition to yield pure hematite nanomaterials, whereas cementite nanomaterials along with α-Fe were obtained in N 2 atmosphere. The obtained materials were mostly agglomerated. Elemental composition of each material was estimated. Using the absorbance data, the energy band gap values were estimated and the related electronic transitions from the observed absorption spectra were explored. Urbach energy was calculated for hematite, which described the role of defects in the decomposed materials. The nanostructures exhibited photoluminescence due to selftrapped states linked to their optical characteristics. Raman spectroscopy of hematite detected seven Raman modes, confirming the rhombohedral structure, whereas the D and G bands were visible in the Raman spectra for cementite. Thus, the reaction atmosphere significantly influenced the thermal decomposition of ferrocene and controls the type of nanomaterials obtained. Plausible reactions of the undergoing solid-state decomposition have been proposed.

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Section: Resultsmentioning

confidence: 99%

Reaction Atmosphere-Controlled Thermal Conversion of Ferrocene to Hematite and Cementite Nanomaterials─Structural and Spectroscopic Investigations

Kundu,

Sarkar,

Ghorai

et al. 2024

ACS Omega

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“…Consequently, it is imperative to eliminate the increasing CO 2 by developing efficient technologies for capturing and converting it. As a green, non-toxic, abundant, and renewable C1 feedstock, CO 2 can be transformed into various valuable energy or chemical products through thermal catalysis, 4,5 photocatalysis, 6,7 photothermal catalysis, 8,9 electrocatalysis, 10,11 and other methodologies. For instance, employing these methods enables the conversion of CO 2 into high-value chemicals such as methane, 12,13 methanol, 14,15 acetic acid, 16 benzimidazole, 17,18 and cyclic carbonate.…”

Section: Introductionmentioning

confidence: 99%

Bimetallic Fe/Co photothermal catalyst for fixing CO₂ to cyclic carbonates under atmospheric pressure

Tu,

Sun,

et al. 2024

Catal. Sci. Technol.

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“…Then protons reduce CO 2 with photogenerated electrons. While the process of H 2 O splitting for hydrogen evolution can supply H + to reduce CO 2 , it simultaneously competes with conduction band electrons for CO 2 reduction, diminishing the effective reduction of CO 2 by photoexcited electrons 30 . Additionally, H 2 O tends to have a higher propensity for surface adsorption on photocatalysts due to its high polarity.…”

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confidence: 99%

Unraveling active sites regulation and temperature-dependent thermodynamic mechanism in photothermocatalytic CO2 conversion with H2O

Zhang,

Li,

Liu

et al. 2024

npj Comput Mater

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In the photothermal synergistic catalytic conversion of CO2 and H2O, the catalyst harnesses solar energy to accumulate heat, thereby elevating the reaction system’s temperature. The influence of this temperature effect on surface chemical reactions remains an underexplored area. Here the impact of temperature on the surface-level thermodynamic reactions and conversion of CO2 with H2O on oxide semiconductors at the atomic scale was investigated using first-principle calculations. 13 different metal oxides and 5 transition metal clusters were used to introduce surface functional sites on the TiO2 supporting catalyst. The potential metal oxide cocatalysts that could be most beneficial to the following conversion of CO2 by H2O were initially screened by calculating the degrees of promotion of CO2 adsorption and activation of surface H to provide protons. The proton donation and hydrogen evolution difficulty from H2O were further analyzed, identifying transition metal cocatalysts that promote direct CO2 hydrogenation. Upon introducing bifunctional sites to facilitate adsorption and reduction, the production of CH3OH and CH4 could be further enhanced through the facilitation of the proton donation process of H2O. The results of Gibbs free-energy calculations revealed that increasing temperature enhances the reaction thermodynamics for each C1 product formation at different surface sites to varying degrees. These findings offer valuable theoretical insights for designing and regulating active sites on oxide semiconductor surfaces for efficient photothermal catalytic CO2 reduction by H2O.

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Photothermal Catalytic CO2 Conversion: Beyond Catalysis and Photocatalysis

Cited by 20 publications

References 118 publications

Reaction Atmosphere-Controlled Thermal Conversion of Ferrocene to Hematite and Cementite Nanomaterials─Structural and Spectroscopic Investigations

Reaction Atmosphere-Controlled Thermal Conversion of Ferrocene to Hematite and Cementite Nanomaterials─Structural and Spectroscopic Investigations

Bimetallic Fe/Co photothermal catalyst for fixing CO₂ to cyclic carbonates under atmospheric pressure

Unraveling active sites regulation and temperature-dependent thermodynamic mechanism in photothermocatalytic CO2 conversion with H2O

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Photothermal Catalytic CO2 Conversion: Beyond Catalysis and Photocatalysis

Cited by 20 publications

References 118 publications

Reaction Atmosphere-Controlled Thermal Conversion of Ferrocene to Hematite and Cementite Nanomaterials─Structural and Spectroscopic Investigations

Reaction Atmosphere-Controlled Thermal Conversion of Ferrocene to Hematite and Cementite Nanomaterials─Structural and Spectroscopic Investigations

Bimetallic Fe/Co photothermal catalyst for fixing CO2 to cyclic carbonates under atmospheric pressure

Unraveling active sites regulation and temperature-dependent thermodynamic mechanism in photothermocatalytic CO2 conversion with H2O

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Bimetallic Fe/Co photothermal catalyst for fixing CO₂ to cyclic carbonates under atmospheric pressure