Role of Reduced CeO<sub>2</sub>(110) Surface for CO<sub>2</sub> Reduction to CO and Methanol

Kumari, Neetu; Haider, M. Ali; Agarwal, Manish; Sinha, Nishant K.; Basu, Suddhasatwa

doi:10.1021/acs.jpcc.6b02860

Cited by 102 publications

(83 citation statements)

References 56 publications

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“…also discovered the promotion role of Ce in methanol generation in their research . To understand the promotion mechanism of Ce from the theoretical level, many research groups performed DFT calculations and they have proved the activation ability of CO 2 at the Cu−CeO 2 interface ,,. However, there is still no systematic study of CeO x as a catalyst promoter in CuZnCeO x catalyst.…”

Section: Introductionmentioning

confidence: 97%

The Synergistic Effect of CuZnCeO_x in Controlling the Formation of Methanol and CO from CO₂ Hydrogenation

Qin

Guan

et al. 2018

ChemCatChem

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CO 2 hydrogenation will be essential for a sustainable society if methanol and CO can be efficiently obtained using appropriate catalysts. In this paper, a highly efficient CuZnCeO x catalyst was synthesized using a parallel flow coprecipitation method, and was evaluated in CO 2 hydrogenation to produce methanol and CO. Interestingly, the catalyst shows excellent activity and stability, and the selectivity of the products can be controlled by the amount of CeO x . Characterization results show that a significant synergistic effect between Cu and metal oxides (ZnO and/or CeO x ) was observed at the composite catalysts. Cu plays a critical role in the activation of H 2 , and CeO x strongly adsorbs CO 2 . CeO x improved the dispersion of Cu nanoparticles and promoted the spillover of atomic hydrogen, which was beneficial to the generation of methanol. Meanwhile, ZnO exhibited weak adsorption ability for CO 2 , which was beneficial for the generation of CO. In addition, ZnO can significantly improve the dispersion of the CeO x nanoparticles. Both the dispersion of active sites and the activation abilities of CO 2 are critical for catalyst activity and product selectivity. Thus, the ternary catalyst CuZnCeO x shows higher performance than the binary catalysts (CuZnO x and CuCeO x ) in the CO 2 hydrogenation reaction. This paper provides a viable way to produce selectively methanol or CO from CO 2 hydrogenation.[a] Dr.

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Section: Introductionmentioning

confidence: 97%

The Synergistic Effect of CuZnCeO_x in Controlling the Formation of Methanol and CO from CO₂ Hydrogenation

Qin

Guan

et al. 2018

ChemCatChem

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“…The former is related to the presence of oxygen vacancies without change of the crystalline structure (typically a fluorite) whereas the latter corresponds to the limit case where all the Ce atoms are reduced into Ce 3+ with a sesquioxide A-type (hexagonal) structure. 10 In the last years, much effort was put in the comprehension of the partial reduction impact on the ceria surface property [11][12][13][14][15][16] and reactivity [17][18][19][20][21] , with much less insight in Ce 2 O 3 compositions. In standard conditions of pressure and temperature, Ce 2 O 3 is not a stable material but recent development of new experimental techniques and protocols make possible the synthesis of Ce 2 O 3 particles.…”

Section: Introductionmentioning

confidence: 99%

H2 Dissociation and Oxygen Vacancy Formation on Ce2O3 Surfaces

Matz

Calatayud

2019

Top Catal

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H 2 dissociation on ceria (CeO 2) has attracted much attention in the last years because of its potential application in catalysis for hydrogenation reactions, as well as for the stabilization of hydride bulk and surface species. The ability of ceria to split hydrogen is strongly dependent on the surface morphology. However, to the best of our knowledge, the reactivity of the cerium sesquioxide Ce 2 O 3 Atype (hexagonal structure with space group 3 1) has not been previously addressed. In the present study, we investigate (i) the formation of oxygen vacancies in ACe 2 O 3 bulk and (ii) the effect of the surface topology in the H 2 dissociation and in the oxygen vacancy formation for the four most stable surfaces of ACe 2 O 3 : (0001), (01-11), (11-20) and (11-21). Our results indicate a significant decrease of the energetic barrier for the hydrogen dissociation compared to stoichiometric CeO 2 , with an activation energy of ~0.1 eV. Interestingly, Ce 2 O 3 surfaces lead to a heterolytic product with hydride species more stable than the homolytic product, which is the opposite behavior found in CeO 2. These results suggest a better performance of Ce 2 O 3 than CeO 2 for H 2 dissociation and provide insight in the nature of hydride-Ce 2 O 3 interfaces that could be important intermediates in the formation of CeH x phases from cerium oxide.

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“…This was also found in the present work for both GDC10 and SDC15, as a relative increase of the carboxylate signal was observed on the pre‐reduced samples. Surface carboxylate or formate are suspected to be the reaction intermediates for the hydrogenation of CO 2 to methanol . As we observed carboxylates (but no formates) on reduced GDC10/SDC15 after CO 2 RT adsorption and subsequent CO 2 ‐TPO, this result might be interpreted in favor of the carboxylate mediated route.…”

Section: Resultsmentioning

confidence: 59%

“…Surface carboxylate or formate are suspected to be the reaction intermediates for the hydrogenation of CO 2 to methanol. [34,35,36] As we observed carboxylates (but no formates) on reduced GDC10/SDC15 after CO 2 RT adsorption and subsequent CO 2 -TPO, this result might be interpreted in favor of the carboxylate mediated route. However, it must be emphasized that our experiments showed the formation of CO (which is the product of the reverse water-gas shift reaction) and not the formation of methanol.…”

Section: Surface Chemical Aspectsmentioning

confidence: 58%

CO₂ Reduction by Hydrogen Pre‐Reduced Acceptor‐Doped Ceria

2019

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The reactivity of H2 pre‐reduced acceptor‐doped ceria materials Gd0.10Ce0.90O2‐δ (GDC10) and Sm0.15Ce0.85O2‐δ (SDC15) was tested with respect to the reduction of CO2 to CO in the context of the reverse water‐gas shift reaction. It was demonstrated that not only oxygen vacancies, but also dissolved hydrogen is a reactive species for the reduction of CO2. Dissolved hydrogen must be considered upon discussion of the mechanism of the reverse water‐gas shift reaction on ceria‐derived materials apart from oxygen vacancies and formates. The reduction of CO2 is preceded by the formation of carbonate species of different thermal stability and reactivity. The stability of these carbonates was directly demonstrated by in situ infrared spectroscopy and revealed the largely reversible nature of CO2 ad‐ and desorption. In comparison to pre‐reduced samples, decreased carbonate coverage is obtained after oxidative treatments of GDC10 and SDC15. No significant effect of the sample treatment (O2 oxidation or H2 reduction) on the surface carbonate stability was noticed. Mono‐dentate carbonates and carboxylates appear to be more easily formed on pre‐reduced (i. e. defective) samples. Ce4+ reduction to Ce3+ (by H2) and re‐oxidation to Ce4+ (by CO2) on GDC10/SDC15 were directly monitored by infrared spectroscopic analysis of a distinct, IR‐active electronic transition of Ce3+. These results show the complex interplay of oxygen vacancy/dissolved hydrogen reactivity and surface chemical aspects in acceptor‐doped ceria materials.

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Role of Reduced CeO₂(110) Surface for CO₂ Reduction to CO and Methanol

Cited by 102 publications

References 56 publications

The Synergistic Effect of CuZnCeO_x in Controlling the Formation of Methanol and CO from CO₂ Hydrogenation

The Synergistic Effect of CuZnCeO_x in Controlling the Formation of Methanol and CO from CO₂ Hydrogenation

H2 Dissociation and Oxygen Vacancy Formation on Ce2O3 Surfaces

CO₂ Reduction by Hydrogen Pre‐Reduced Acceptor‐Doped Ceria

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Role of Reduced CeO2(110) Surface for CO2 Reduction to CO and Methanol

Cited by 102 publications

References 56 publications

The Synergistic Effect of CuZnCeOx in Controlling the Formation of Methanol and CO from CO2 Hydrogenation

The Synergistic Effect of CuZnCeOx in Controlling the Formation of Methanol and CO from CO2 Hydrogenation

H2 Dissociation and Oxygen Vacancy Formation on Ce2O3 Surfaces

CO2 Reduction by Hydrogen Pre‐Reduced Acceptor‐Doped Ceria

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Product

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Role of Reduced CeO₂(110) Surface for CO₂ Reduction to CO and Methanol

The Synergistic Effect of CuZnCeO_x in Controlling the Formation of Methanol and CO from CO₂ Hydrogenation

The Synergistic Effect of CuZnCeO_x in Controlling the Formation of Methanol and CO from CO₂ Hydrogenation

CO₂ Reduction by Hydrogen Pre‐Reduced Acceptor‐Doped Ceria