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

Zhang, Li; Li, Changqi; Liu, Yan; Xu, Chenyu; Zhang, Yanwei

doi:10.1038/s41524-024-01325-3

“…It is well established that nitrogen doping in carbon materials could lead to charge redistribution, resulting in the formation of electron-rich regions. Furthermore, high-temperature treatment is likely to enhance the formation of surface-active sites, such as pyridine and pyrrole nitrogen. , The CO 2 -TPD technique was employed to examine the basicity and strength of the Fe@NC- T nanosphere catalysts. In general, this methodology provides insights into the basic surface characteristics of catalysts by associating the temperature range and cumulative area of the CO 2 desorption peaks with the strength and abundance of basic sites.…”

Section: Resultsmentioning

confidence: 99%

Ultralow Loading Fe on N-Doped Carbon Nanospheres for Anaerobic Cleavage of C–C Bonds in Biomass Vicinal Diols

Mao,

Wang,

Zhou

et al. 2024

ACS Appl. Nano Mater.

0

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The efficient and selective conversion of biomass-derived vicinal diols into high-value-added chemicals represents a pivotal area of research that has garnered substantial interest within the scientific community. In this work, three ultralow loading Fe supports on N-doped carbon nanosphere catalysts (Fe@NC-T) were successfully prepared using the hard template method with acid etching. The selective conversion of vicinal diols into aldehydes, ketones, and amines over the Fe@NC-800 nanosphere catalyst was achieved through an anaerobic cleavage of C−C bonds and successfully utilized autologous hydrogen resources. The exceptional catalytic activity of the Fe@NC-800 nanosphere catalyst may be credited to the presence of highly dispersed Fe species at the active sites, which has been verified through several characterization techniques, control tests, and density functional theory calculations. In addition, the Fe@NC-800 nanosphere catalyst also demonstrated its wide applicability and excellent reusability under the operating conditions. We believe that this study presents an auspicious scheme for the highly selective conversion of vicinal diols into high value-added carbonyl compounds and amine products.

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Near‐Unity Photothermal CO₂ Hydrogenation to Methanol Based on a Molecule/Nanocarbon Hybrid Catalyst

Ren,

Han,

Yang

et al. 2024

Angewandte Chemie

0

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Solar‐driven CO2‐to‐methanol conversion provides an intriguing route for both solar energy storage and CO2 mitigation. For scalable applications, near‐unity methanol selectivity is highly desirable to reduce the energy and cost endowed by low‐value byproducts and complex separation processes, but so far has not been achieved. Here we demonstrate a molecule/nanocarbon hybrid catalyst composed of carbon nanotube‐supported molecularly dispersed cobalt phthalocyanine (CoPc/CNT), which synergistically integrates high photothermal conversion capability for affording an optimal reaction temperature with homogeneous and intrinsically‐efficient active sites, to achieve a catalytic activity of 2.4 mmol gcat‐1 h‐1 and selectivity of ~99% in direct photothermal CO2 hydrogenation to methanol reaction. Both theoretical calculations and operando characterizations consistently confirm that the unique electronic structure of CoPc and appropriate reaction temperature cooperatively enable a thermodynamic favorable reaction pathway for highly selective methanol production. This work represents an important milestone towards the development of advanced photothermal catalysts for scalable and cost‐effective CO2 hydrogenation.

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Near‐Unity Photothermal CO₂ Hydrogenation to Methanol Based on a Molecule/Nanocarbon Hybrid Catalyst

Ren,

Han,

Yang

et al. 2024

Angew Chem Int Ed

0

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Solar‐driven CO2‐to‐methanol conversion provides an intriguing route for both solar energy storage and CO2 mitigation. For scalable applications, near‐unity methanol selectivity is highly desirable to reduce the energy and cost endowed by low‐value byproducts and complex separation processes, but so far has not been achieved. Here we demonstrate a molecule/nanocarbon hybrid catalyst composed of carbon nanotube‐supported molecularly dispersed cobalt phthalocyanine (CoPc/CNT), which synergistically integrates high photothermal conversion capability for affording an optimal reaction temperature with homogeneous and intrinsically‐efficient active sites, to achieve a catalytic activity of 2.4 mmol gcat‐1 h‐1 and selectivity of ~99% in direct photothermal CO2 hydrogenation to methanol reaction. Both theoretical calculations and operando characterizations consistently confirm that the unique electronic structure of CoPc and appropriate reaction temperature cooperatively enable a thermodynamic favorable reaction pathway for highly selective methanol production. This work represents an important milestone towards the development of advanced photothermal catalysts for scalable and cost‐effective CO2 hydrogenation.

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

Cited by 4 publications

References 85 publications

Ultralow Loading Fe on N-Doped Carbon Nanospheres for Anaerobic Cleavage of C–C Bonds in Biomass Vicinal Diols

Ultralow Loading Fe on N-Doped Carbon Nanospheres for Anaerobic Cleavage of C–C Bonds in Biomass Vicinal Diols

Near‐Unity Photothermal CO₂ Hydrogenation to Methanol Based on a Molecule/Nanocarbon Hybrid Catalyst

Near‐Unity Photothermal CO₂ Hydrogenation to Methanol Based on a Molecule/Nanocarbon Hybrid Catalyst

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

Cited by 4 publications

References 85 publications

Ultralow Loading Fe on N-Doped Carbon Nanospheres for Anaerobic Cleavage of C–C Bonds in Biomass Vicinal Diols

Ultralow Loading Fe on N-Doped Carbon Nanospheres for Anaerobic Cleavage of C–C Bonds in Biomass Vicinal Diols

Near‐Unity Photothermal CO2 Hydrogenation to Methanol Based on a Molecule/Nanocarbon Hybrid Catalyst

Near‐Unity Photothermal CO2 Hydrogenation to Methanol Based on a Molecule/Nanocarbon Hybrid Catalyst

Contact Info

Product

Resources

About

Near‐Unity Photothermal CO₂ Hydrogenation to Methanol Based on a Molecule/Nanocarbon Hybrid Catalyst

Near‐Unity Photothermal CO₂ Hydrogenation to Methanol Based on a Molecule/Nanocarbon Hybrid Catalyst