Synergistic Effect of Simultaneous Doping of Ceria Nanorods with Cu and Cr on CO Oxidation and NO Reduction

Rood, Shawn; Pastor‐Algaba, Oriol; Tosca‐Princep, Albert; Pinho, Bruno; Isaacs, Mark A.; Torrente‐Murciano, Laura; Eslava, Salvador

doi:10.1002/chem.202004623

Cited by 14 publications

(11 citation statements)

References 80 publications

(165 reference statements)

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“…Other groups have shown that morphology control is possible: samples with 5 and 10 mol% Cu were made using chlorides and H2O2 heated at 180 °C, and 5 h of heating produced spheres with diameters of 60-80 nm, Figure 4, [57], while addition of PVP, ammonia and urea to the mixture with heating for 6 h gave spheres of ~100 nm in diameter [58]. Rood et al were able to synthesise Cu-containing ceria nanotubes that were single phase up to 7 mol% Cu [59]. Their method involved using Ce(NO3)3 and CuSO4 in NaOH solution heated to 100 °C for 10 h. In the same work, Cr-containing ceria nanotubes, up to a concentration of 5 mol%, were reported where a similar method was used, with Cr(NO3)3 as a precursor.…”

Section: Transition Metal-substituted Ceriasmentioning

confidence: 99%

“…Their method involved using Ce(NO3)3 and CuSO4 in NaOH solution heated to 100 °C for 10 h. In the same work, Cr-containing ceria nanotubes, up to a concentration of 5 mol%, were reported where a similar method was used, with Cr(NO3)3 as a precursor. These materials were tested as catalysts for both CO oxidation and NO reduction, with the Cu samples outperforming pure CeO2 in terms of CO oxida- Rood et al were able to synthesise Cu-containing ceria nanotubes that were single phase up to 7 mol% Cu [59]. Their method involved using Ce(NO 3 ) 3 and CuSO 4 in NaOH solution heated to 100 • C for 10 h. In the same work, Cr-containing ceria nanotubes, up to a concentration of 5 mol%, were reported where a similar method was used, with Cr(NO 3 ) 3 as a precursor.…”

Section: Transition Metal-substituted Ceriasmentioning

confidence: 99%

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Solvothermal Synthesis Routes to Substituted Cerium Dioxide Materials

et al. 2021

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We review the solution-based synthesis routes to cerium oxide materials where one or more elements are included in place of a proportion of the cerium, i.e., substitution of cerium is performed. The focus is on the solvothermal method, where reagents are heated above the boiling point of the solvent to induce crystallisation directly from the solution. This yields unusual compositions with crystal morphology often on the nanoscale. Chemical elements from all parts of the periodic table are considered, from transition metals to main group elements and the rare earths, including isovalent and aliovalent cations, and surveyed using the literature published in the past ten years. We illustrate the versatility of this synthesis method to allow the formation of functional materials with applications in contemporary applications such as heterogeneous catalysis, electrodes for solid oxide fuel cells, photocatalysis, luminescence and biomedicine. We pick out emerging trends towards control of crystal habit by use of non-aqueous solvents and solution additives and identify challenges still remaining, including in detailed structural characterisation, the understanding of crystallisation mechanisms and the scale-up of synthesis.

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Section: Transition Metal-substituted Ceriasmentioning

confidence: 99%

Section: Transition Metal-substituted Ceriasmentioning

confidence: 99%

Solvothermal Synthesis Routes to Substituted Cerium Dioxide Materials

et al. 2021

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“…[32] The Cu 2p spectra (Figure 4c) reveal that the copper dopants embrace Cu 2 + and Cu + species, as evidenced by the observation of the two typical peaks at 934.8 eV and 933.4 eV. [21,25] Interestingly, the low coordinated Cu + species was not detected in the CuCrCe catalysts, due to the coupling of the redox cycles of Cr VI /Cr III and Cu II /Cu I , i. e. the Cu + species can be easily oxidized to Cu 2 + by Cr 6 + species consistent with the results of H 2 -TPR (Figure 2b). [33] It is another indication of the co-existence of the copper and chromium in the CuCrCe catalysts.…”

Section: Chemcatchemmentioning

confidence: 96%

“…[23] In a previous comparative study of different configurations of copper-ceria catalysts, we showed that a solid solution with copper incorporated into the ceria lattice exhibits superior catalytic performance in the NO reduction with CO compared to corresponding catalysts made up of copper oxide particles supported on ceria and ball-milled mechanical mixtures of these components. [24] Recently, Rood et al demonstrated that copper and chromium doping into the crystal lattice of ceria nanorods exposing the (111) facets increases the concentration of oxygen defects and the surface and bulk reducibility leading to enhanced N 2 -selectivity in the reduction of NO with CO. [25] These findings prompted us to prepare multicomponent CuCrCeO x , CuCeO x , and CrCeO x solid solution catalysts to study the synergy of Cu and Cr co-doping in the NO reduction with CO in the presence as well as absence of oxygen and to evaluate the influence of water and SO 2 on the catalyst stability.…”

Section: Introductionmentioning

confidence: 99%

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Ternary CuCrCeO_x Solid Solution Enhances N₂‐Selectivity in the NO Reduction with CO in the Presence of Water and Oxygen

et al. 2022

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Co‐doping of ceria with Cu and Cr forming a ternary CuCrCeOx solid solution enhances N2‐selectivity as well as NO and CO conversions compared to the corresponding singly doped ceria, CuCeOx and CrCeOx, and pristine ceria, in the absence as well as presence of water and oxygen. The comparative study of these solid‐solution catalysts indicates that the doping of ceria results in the coupling of different transition metal redox cycles, which has a strong effect on the surface population of oxygen vacancies. The temperature required to reach 95 % N2‐selectivity is shown to be nearly linearly correlated to the concentration of oxygen vacancy defects. The oxygen defect population is highest for the ternary CuCrCeOx solid solution, which exhibits the best catalytic performance, reaching 100 % N2‐selectivity at around 100 °C. Three redox cycles (CrVI/CrIII, CuII/CuI, and CeIV/CeIII) have been identified in this catalyst leading to a synergistic effect. The ternary CuCrCeOx catalyst exhibits good water tolerance and long‐term stability while the SO2 tolerance is limited due to selective blocking of the active surface oxygen defects forming SO32− species, resulting in catalyst deactivation.

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Research progress of metal oxide supports for fuel cells electrocatalysts

Zhang,

Liu,

Wang

et al. 2024

ChemistrySelect

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Fuel cell technology, as a new way of energy conversion, is widely used in various fields. At present, the electrocatalyst, as one of the key components of the electrochemical reaction of fuel cells, still suffers from the problems of high cost, low activity and poor stability. Excellent fuel cell electrocatalysts must have excellent catalytic activity, anti‐poisoning ability, electrical conductivity and stability. Metal oxides with corrosion resistance, electrochemical stability and strong metal support interaction effects have been intensively studied. The influence of the synthesis method on the catalytic performance is also crucial. In this review, the importance of fuel cells and their catalysts is introduced. The characteristics of catalysts with three metal oxides, titanium dioxide, cerium dioxide and tungsten oxide, as supports, preparation methods and applications in different fuel cells are reviewed. The synthesis of metal oxide supported catalysts by impregnation, precipitation and hydrothermal methods is described. Finally, the research on metal oxide supported catalysts is prospected.

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Synergistic Effect of Simultaneous Doping of Ceria Nanorods with Cu and Cr on CO Oxidation and NO Reduction

Cited by 14 publications

References 80 publications

Solvothermal Synthesis Routes to Substituted Cerium Dioxide Materials

Solvothermal Synthesis Routes to Substituted Cerium Dioxide Materials

Ternary CuCrCeO_x Solid Solution Enhances N₂‐Selectivity in the NO Reduction with CO in the Presence of Water and Oxygen

Research progress of metal oxide supports for fuel cells electrocatalysts

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Synergistic Effect of Simultaneous Doping of Ceria Nanorods with Cu and Cr on CO Oxidation and NO Reduction

Cited by 14 publications

References 80 publications

Solvothermal Synthesis Routes to Substituted Cerium Dioxide Materials

Solvothermal Synthesis Routes to Substituted Cerium Dioxide Materials

Ternary CuCrCeOx Solid Solution Enhances N2‐Selectivity in the NO Reduction with CO in the Presence of Water and Oxygen

Research progress of metal oxide supports for fuel cells electrocatalysts

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Ternary CuCrCeO_x Solid Solution Enhances N₂‐Selectivity in the NO Reduction with CO in the Presence of Water and Oxygen