Importance of the Metal–Oxide Interface in Catalysis: In Situ Studies of the Water–Gas Shift Reaction by Ambient‐Pressure X‐ray Photoelectron Spectroscopy

Mudiyanselage, Kumudu; Senanayake, Sanjaya D.; Feria, Leticia; Kundu, Shankhamala; Baber, Ashleigh E.; Graciani, Jesús; Vidal, Alba B.; Agnoli, Stefano; Evans, Jonathan P.; Chang, Rui; Axnanda, Stephanus; Liu, Zhi; Sanz, Javier Fdez.; Liu, Ping; Rodríguez, José A.; Stacchiola, Darı́o

doi:10.1002/anie.201210077

Cited by 295 publications

(301 citation statements)

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“…After adding another 200 mTorr of H2O into the reaction to make a ~5:1 (H2O/EtOH) vapor mixture, deconvolution of the spectrum shows an extra gas phase feature at 536.0 eV for 200 mTorr water vapor. [32][33] Moreover, the peak intensity of the ceria lattice O is significantly attenuated, which is mainly a result of the increased scattering of photoelectron due to the higher concentration of gas as well as surface adsorbed species between the ceria film and analyzer cone. The catalyst was then heated from 300 to 700 K by 100 K increments in an ambient of 40 mTorr ethanol and 200 mTorr H2O, and the corresponding AP-XPS results for the C 1s, O 1s and Ce 4d regions are shown in Figure 2.…”

Section: Resultsmentioning

confidence: 99%

Ambient pressure XPS and IRRAS investigation of ethanol steam reforming on Ni–CeO₂(111) catalysts: an in situ study of C–C and O–H bond scission

Liu

Duchoň

Wang

et al. 2016

Phys. Chem. Chem. Phys.

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Section: Resultsmentioning

confidence: 99%

Ambient pressure XPS and IRRAS investigation of ethanol steam reforming on Ni–CeO₂(111) catalysts: an in situ study of C–C and O–H bond scission

Liu

Duchoň

Wang

et al. 2016

Phys. Chem. Chem. Phys.

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“…[28][29][30][31][32][33][34][35][36][37] Rodriguez et al studied WGS over Au/TiO 2 (110), and on the basis of experiments and theoretical calculations they concluded that the metalsupport interface is critical for the activation of water and the formation of a carboxyl intermediate which further decomposes into CO 2 and H 2 . 29 Ribeiro and co-workers elucidated the effect of the interface on water activation and determined that the WGS reaction rate scales linearly with the number of under-coordinated Au atoms, estimated from physical models of Au clusters and particle size measurements.…”

Section: Introductionmentioning

confidence: 99%

Reverse Water–Gas Shift on Interfacial Sites Formed by Deposition of Oxidized Molybdenum Moieties onto Gold Nanoparticles

Carrasquillo‐Flores

Kumbhalkar

et al. 2015

J. Am. Chem. Soc.

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We show that MoO(x)-promoted Au/SiO2 catalysts are active for reverse water-gas shift (RWGS) at 573 K. Results from reactivity measurements, CO FTIR studies, Raman spectroscopy, and X-ray absorption spectroscopy (XAS) indicate that the deposition of Mo onto Au nanoparticles occurs preferentially on under-coordinated Au sites, forming Au/MoO(x) interfacial sites active for reverse water-gas shift (RWGS). Au and AuMo sites are quantified from FTIR spectra of adsorbed CO collected at subambient temperatures (e.g., 150-270 K). Bands at 2111 and 2122 cm(-1) are attributed to CO adsorbed on under-coordinated Au(0) and Au(δ+) species, respectively. Clausius-Clapeyron analysis of FTIR data yields a heat of CO adsorption (ΔH(ads)) of -31 kJ mol(-1) for Au(0) and -64 kJ mol(-1) for Au(δ+) at 33% surface coverage. Correlations of RWGS reactivity with changes in FTIR spectra for samples containing different amounts of Mo indicate that interfacial sites are an order of magnitude more active than Au sites for RWGS. Raman spectra of Mo/SiO2 show a feature at 975 cm(-1), attributed to a dioxo (O═)2Mo(-O-Si)2 species not observed in spectra of AuMo/SiO2 catalysts, indicating preferential deposition of Mo on Au. XAS results indicate that Mo is in a +6 oxidation state, and therefore Au and Mo exist as a metal-metal oxide combination. Catalyst calcination increases the quantity of under-coordinated Au sites, increasing RWGS activity. This strategy for catalyst synthesis and characterization enables quantification of Au active sites and interfacial sites, and this approach may be extended to describe reactivity changes observed in other reactions on supported gold catalysts.

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“…23,24,25,26,27 For example, experimental and theoretical studies for the CeO x /Cu and CeO x /TiO 2 systems have shown that at small coverages of ceria, the ceria nanoparticles favor a +3 oxidation state. 28,29,30,31 Furthermore, in an oxide-metal interface, in addition to the changes in the reducibility of the oxide, one can also observe a perturbation in the electronic properties of the metal. 32,33,34,35,36 Electronic perturbations can also occur after forming a carbide-metal interface.…”

Section: Introductionmentioning

confidence: 99%

Hydrogenation of CO₂ to Methanol: Importance of Metal–Oxide and Metal–Carbide Interfaces in the Activation of CO₂

et al. 2015

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The high thermochemical stability of CO 2 makes very difficult the catalytic conversion of the molecule into alcohols or other hydrocarbon compounds which can be used as fuels or the starting point for the generation of fine chemicals. Pure metals and bimetallic systems used for the CO 2 → CH 3 OH conversion usually bind CO 2 too weakly and, thus, show low catalytic activity. Here, we discuss a series of recent studies that illustrate the advantages of metal-oxide and metal-carbide interfaces when aiming at the conversion of CO 2 into methanol. CeO x /Cu(111), Cu/CeO x /TiO 2 (110) andAu/CeO x /TiO 2 (110) exhibit an activity for the CO 2 → CH 3 OH conversion that is 2-3 orders of magnitude higher than that of a benchmark Cu(111) catalyst. In the Cu-ceria and Au-ceria interfaces, the multifunctional combination of metal and oxide centers leads to complementary chemical properties that open active reaction pathways for methanol synthesis. Efficient catalysts are also generated after depositing Cu and Au on TiC(001). In these cases, strong-metal support interactions modify the electronic properties of the admetals and make them active for the binding of CO 2 and its subsequent transformation into CH 3 OH at the metal-carbide interfaces.

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Importance of the Metal–Oxide Interface in Catalysis: In Situ Studies of the Water–Gas Shift Reaction by Ambient‐Pressure X‐ray Photoelectron Spectroscopy

Cited by 295 publications

References 36 publications

Ambient pressure XPS and IRRAS investigation of ethanol steam reforming on Ni–CeO₂(111) catalysts: an in situ study of C–C and O–H bond scission

Ambient pressure XPS and IRRAS investigation of ethanol steam reforming on Ni–CeO₂(111) catalysts: an in situ study of C–C and O–H bond scission

Reverse Water–Gas Shift on Interfacial Sites Formed by Deposition of Oxidized Molybdenum Moieties onto Gold Nanoparticles

Hydrogenation of CO₂ to Methanol: Importance of Metal–Oxide and Metal–Carbide Interfaces in the Activation of CO₂

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Importance of the Metal–Oxide Interface in Catalysis: In Situ Studies of the Water–Gas Shift Reaction by Ambient‐Pressure X‐ray Photoelectron Spectroscopy

Cited by 295 publications

References 36 publications

Ambient pressure XPS and IRRAS investigation of ethanol steam reforming on Ni–CeO2(111) catalysts: an in situ study of C–C and O–H bond scission

Ambient pressure XPS and IRRAS investigation of ethanol steam reforming on Ni–CeO2(111) catalysts: an in situ study of C–C and O–H bond scission

Reverse Water–Gas Shift on Interfacial Sites Formed by Deposition of Oxidized Molybdenum Moieties onto Gold Nanoparticles

Hydrogenation of CO2 to Methanol: Importance of Metal–Oxide and Metal–Carbide Interfaces in the Activation of CO2

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Ambient pressure XPS and IRRAS investigation of ethanol steam reforming on Ni–CeO₂(111) catalysts: an in situ study of C–C and O–H bond scission

Ambient pressure XPS and IRRAS investigation of ethanol steam reforming on Ni–CeO₂(111) catalysts: an in situ study of C–C and O–H bond scission

Hydrogenation of CO₂ to Methanol: Importance of Metal–Oxide and Metal–Carbide Interfaces in the Activation of CO₂