The nature of active sites for carbon dioxide electroreduction over oxide-derived copper catalysts

Cheng, Dongfang; Zhao, Zhi‐Jian; Zhang, Gong; Yang, Ping; Li, Lulu; Gao, Hui; Liu, Sihang; Chang, Xin; Chen, Sai; Wang, Tuo; Ozin, Geoffrey A.; Liu, Zhi-Pan; Gong, Jinlong

doi:10.1038/s41467-020-20615-0

Cited by 203 publications

(183 citation statements)

References 49 publications

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“…A better cohesion between Cu species and the protective carbon layer may be due to a stronger oxidative role of ionic copper species [58] compared to ionic molybdenum species [59] according to Equations (3)- (8).…”

Section: Catalystsmentioning

confidence: 99%

Photocatalytic Performance of Carbon-Containing CuMo-Based Catalysts under Sunlight Illumination

et al. 2022

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Carbon-doped nanostructured CuMo-based photocatalysts were prepared by solvothermal synthesis. Two thermal treatments—oxidative and inert atmosphere—were used for the synthesis of the catalysts, and the influence of spherical carbon structures upon the crystalline phases on the photocatalytic activity and stability was studied. XRD showed the catalysts are nanostructured and composed by a mixture of copper (Cu, Cu2O, and CuO) and molybdenum (MoO2 and MoO3) crystalline phases. The catalysts were used for the degradation of yellow 5 under solar light. A remarkable leaching of Mo both in dark and under solar irradiation was observed and quantified. This phenomenon was responsible for the loss of photocatalytic activity for the degradation of the dye on the Mo-containing series. Conversely, the Cu-based photocatalysts were stable, with no leaching observed after 6 h irradiation and with a higher conversion of yellow 5 compared with the Mo- and CuMo series. The stability of Cu-based catalysts was attributed to a protective effect of spherical carbon structures formed during the solvothermal synthesis. Regarding the catalysts’ composition, sample Cu4-800-N2 prepared by pyrolysis exhibited up to 4.4 times higher photoactivity than that of the pristine material, which is attributed to a combined effect of an enhanced surface area and micropore volume generated during the pyrolytic treatment due to the presence of the carbon component in the catalyst. Scavenger tests have revealed that the mechanism for tartrazine degradation on irradiated Cu-based catalysts involves successive attacks of •OH radicals.

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Section: Catalystsmentioning

confidence: 99%

Photocatalytic Performance of Carbon-Containing CuMo-Based Catalysts under Sunlight Illumination

et al. 2022

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“…Moreover, when comparing intermediates that could be related to reaction pathway bifurcations, we see that HCOO and CHO are more affected by the coordination than COOH and COH, which can lead to coordination-dependent pathways for different reactions as already observed in the literature. 48–50 Fig. 2 also shows through the magnitudes of the coefficient of determination, r 2 and the mean absolute error, MAE, that the GCN values can be used, to a certain extent, to explain the variation of E bind as a function of the adsorption site coordination.…”

Section: Resultsmentioning

confidence: 98%

Exploring the adsorption site coordination as a strategy to tune copper catalysts for CO₂ electro-reduction

Verga

Mendes

Ocampo-Restrepo

et al. 2022

Catal. Sci. Technol.

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“…(b) Proportions of different surface structures of the OD-Cu model. Reprinted from ref ( 181 ) under a Creative Commons CC BY License. (c) Snapshots from the MC simulation of a large (211) surface slab model with solvent, containing in total ∼6500 atoms.…”

Section: Modeling Strategies For Realistic Simulationmentioning

confidence: 99%

Dynamics of Heterogeneous Catalytic Processes at Operando Conditions

Shi

Lin

Luo

et al. 2021

JACS Au

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The rational design of high-performance catalysts is hindered by the lack of knowledge of the structures of active sites and the reaction pathways under reaction conditions, which can be ideally addressed by an in situ / operando characterization. Besides the experimental insights, a theoretical investigation that simulates reaction conditions—so-called operando modeling—is necessary for a plausible understanding of a working catalyst system at the atomic scale. However, there is still a huge gap between the current widely used computational model and the concept of operando modeling, which should be achieved through multiscale computational modeling. This Perspective describes various modeling approaches and machine learning techniques that step toward operando modeling, followed by selected experimental examples that present an operando understanding in the thermo- and electrocatalytic processes. At last, the remaining challenges in this area are outlined.

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The nature of active sites for carbon dioxide electroreduction over oxide-derived copper catalysts

Cited by 203 publications

References 49 publications

Photocatalytic Performance of Carbon-Containing CuMo-Based Catalysts under Sunlight Illumination

Photocatalytic Performance of Carbon-Containing CuMo-Based Catalysts under Sunlight Illumination

Exploring the adsorption site coordination as a strategy to tune copper catalysts for CO₂ electro-reduction

Dynamics of Heterogeneous Catalytic Processes at Operando Conditions

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The nature of active sites for carbon dioxide electroreduction over oxide-derived copper catalysts

Cited by 203 publications

References 49 publications

Photocatalytic Performance of Carbon-Containing CuMo-Based Catalysts under Sunlight Illumination

Photocatalytic Performance of Carbon-Containing CuMo-Based Catalysts under Sunlight Illumination

Exploring the adsorption site coordination as a strategy to tune copper catalysts for CO2 electro-reduction

Dynamics of Heterogeneous Catalytic Processes at Operando Conditions

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Product

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Exploring the adsorption site coordination as a strategy to tune copper catalysts for CO₂ electro-reduction