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4. Water-methanol solutions characterized by liquid $\mu$-jet XPS and DFT; the methanol hydration case

Author

Pellegrin, Eric, Perez-Dieste, Virginia, Escudero, Carlos, Fraxedas, Jordi, Rejmak, Pawel, Gonzalez, Nahikari, Fontsere, Abel, Prat, Jordi, and Ferrer, Salvador

Subjects
Physics - Atomic and Molecular Clusters
Abstract

The advent of liquid $\mu$-jet setups as proposed by Faubel and Winter in conjunction with X-ray Photoemission Spectroscopy (XPS) has opened up a large variety of experimental possibilities in the field of atomic and molecular physics. In this study, we present first results from a synchrotron-based XPS core level and valence band electron spectroscopy study on water (10$^{-4}$M aqueous NaCl solution) as well as a water-methanol mixture using the newly commissioned ALBA liquid $\mu$-jet setup. The experimental results are compared with simulations from density functional theory (DFT) regarding the electronic structure of single molecules, pure molecular clusters, and mixed clusters configurations as well as previous experimental studies. We give a detailed interpretation of the core level and valence band spectra for the vapour and liquid phases of both sample systems. The resulting overall picture gives insight into the water-methanol concentrations of the vapour and liquid phases as well as into the local electronic structure of the pertinent molecular clusters under consideration, with a special emphasis on methanol as the simplest amphiphilic molecule capable of creating hydrogen bonds., Comment: 29 pages, 14 figures

Published
2019

12. Molecular elucidation of CO2 methanation over a highly active, selective and stable LaNiO3/CeO2-derived catalyst by in situ FTIR and NAP-XPS

Author

Universidad de Alicante. Departamento de Química Inorgánica, Onrubia-Calvo, Jon A., López-Rodríguez, Sergio, Villar-Garcia, Ignacio J., Perez Dieste, Virginia, Bueno López, Agustín, González-Velasco, Juan R., Universidad de Alicante. Departamento de Química Inorgánica, Onrubia-Calvo, Jon A., López-Rodríguez, Sergio, Villar-Garcia, Ignacio J., Perez Dieste, Virginia, Bueno López, Agustín, and González-Velasco, Juan R.

Abstract

The CO2 methanation mechanism over the highly active (TOF=75.1 h−1), selective (>92%) and stable 10% LaNiO3/CeO2-derived catalyst is still unresolved. The surface of the catalyst is monitored under hydrogenation (H2), oxidizing (CO2) and CO2 methanation (H2 +CO2) conditions by near ambient pressure X-ray photoelectron spectroscopy (NAP-XPS) using synchrotron radiation. Meanwhile, the main reaction intermediates are identified by in situ FTIR analysis. NAP-XPS experiments confirm that LaNiO3 perovskite reduction leads to the ex-solution of Ni0 nanoparticles and Ni2+single bondCeO2−x and Ni2+single bondLa2O3 interfaces conformation, favouring the CO2 adsorption and the H2 dissociation/transfer. In situ FTIR experiments combined with the C1s spectra (NAP-XPS) suggest that the CO2 activation occurs on CeO2−x (oxygen vacancies and OH–) at low temperatures, in the form of bicarbonates; whereas, mono-/bidentate carbonates are formed on different strength La2O3 sites at increasing temperatures. These species are consecutively reduced to formates, as the main reaction intermediate, and methane by the H spilled from Ni0 nanoparticles near to NiOsingle bondCeO2−x and NiOsingle bondLa2O3 interfaces.

Published
2023

14. Monitoring by in situ NAP-XPS of active sites for CO2 methanation on a Ni/CeO2 catalyst

Author

Universidad de Alicante. Departamento de Química Inorgánica, López-Rodríguez, Sergio, Davó-Quiñonero, Arantxa, Bailón-García, Esther, Lozano-Castello, Dolores, Villar-Garcia, Ignacio J., Perez Dieste, Virginia, Onrubia-Calvo, Jon A., González-Velasco, Juan R., Bueno López, Agustín, Universidad de Alicante. Departamento de Química Inorgánica, López-Rodríguez, Sergio, Davó-Quiñonero, Arantxa, Bailón-García, Esther, Lozano-Castello, Dolores, Villar-Garcia, Ignacio J., Perez Dieste, Virginia, Onrubia-Calvo, Jon A., González-Velasco, Juan R., and Bueno López, Agustín

Abstract

Ni/CeO2 catalysts are very active and selective for total hydrogenation of CO2 to methane, but the nature of the active sites is still unclear. The surface of a Ni/CeO2 catalyst has been monitored under CO2 methanation conditions by Near Ambient Pressure-XPS (NAP-XPS) using synchrotron radiation, and has been concluded that the species involved in the redox processes taking place during the CO2 methanation mechanism are the Ni2+-CeO2/Ni0 and Ce4+/Ce3+ pairs. In addition, a small fraction of nickel is present on the catalyst surface forming NiO and Ni2+-carbonates/hydroxyls (around 20% of the total surface nickel), but these species do not participate in the redox processes of the methanation mechanism. Under CO2 methanation conditions the H2 reduction rate of the Ni2+-CeO2/Ni0 and Ce4+/Ce3+ couples is much faster than their CO2 reoxidation rate (2 times faster, at least, at 300ºC), but a certain proportion of nickel always remains oxidized under reaction conditions. The high activity of Ni/CeO2 catalysts for CO2 methanation is tentatively attributed to the simultaneous presence of Ni2+-CeO2 and Ni0 active sites where CO2 and H2 are expected to be efficiently dissociated, respectively.

Published
2022

15. In situevolution of surface and bulk properties of Ni/La-doped CeO2catalysts for CO2reduction with hydrogen

Author

Bachiller-Baeza, Belén, Rodrigues, João Elias F.S., Capel-Sanchez, Maricarmen, Gainza, Javier, García-Sánchez, Victoria E., Villar-García, Ignacio J., Perez-Dieste, Virginia, Marini, Carlo, Fernández-Diaz, M. Teresa, Alonso, José A., and Álvarez-Galván, Consuelo

Abstract

In this work, key factors that affect catalytic activity of Ni/La-doped ceria catalysts for the reverse water gas shift reaction (RWGS) have been revealed by applying in situ advanced synchrotron techniques, such as X-ray Absorption Spectroscopy (XAS) and Near-ambient pressure X-ray Photoelectron spectroscopy (NAP-XPS). Complementary ex situ characterization techniques have been also used, adding valuable insights on different physicochemical properties of the catalysts. Lanthanum incorporates into the ceria lattice, increasing oxygen mobility, which has a role in the formation of H2O during the reaction. The optimum substitution degree of Ce by La that maximizes CO yield is close to 10 %. It is found that both bulk and surface Ce3+proportions depend on the proportion of La, increasing with La content. At a reaction temperature of 873 K, bulk Ce3+proportions are higher than surface ones. These differences are due to oxidative phenomena, associated to the reactive mixture that take place on the surface, such as CO2adsorption and H2O formation. Concerning Ni phase, NiO bulk reduction to metallic Ni is very fast (in the range 573–623 K), however, Ni0and Ni2+species coexist on the surface during the reaction. It is found that a higher proportion of surface metallic Ni promotes the selectivity towards the RWGS, inhibiting the competing methanation reaction. On the other hand, La doping is relevant for the formation of lanthanum oxycarbonate, which has a role gasifying carbon deposits.

Published
2024
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16. Redox Properties of Cu2O(100) and (111) Surfaces

Author

Wang, Chunlei, Tissot, Heloise, Escudero, Carlos, Perez-Dieste, Virginia, Stacchiola, Dario, Weissenrieder, Jonas, Wang, Chunlei, Tissot, Heloise, Escudero, Carlos, Perez-Dieste, Virginia, Stacchiola, Dario, and Weissenrieder, Jonas

Abstract

Intense research efforts are directed toward Cu and Cu2O based catalysts as they are viewed as potential replacements for noble metal catalysts. However, applications are hampered by deactivation, e.g., through facile complete oxidation to CuO. Despite the importance of the redox processes for Cu2O catalysts, a molecular level understanding of the deactivation process is still lacking. Here we study the initial stages of oxidization of well-defined Cu2O bulk single crystals of (100) and (111) termination by means of synchrotron radiation X-ray photoemission spectroscopy (XPS) and scanning tunneling microscopy (STM). Exposure of the (100) surface to 1 mbar O-2 at 25 degrees C results in the formation of a 1.0 monolayer (ML) CuO surface oxide. The surface is covered by 0.7 ML OH groups from trace moisture in the reaction gas. In contrast, neither hydroxylation nor oxidation was observed on the (111) surface under similar mild exposure conditions. On Cu2O(111) the initial formation of CuO requires annealing to similar to 400 degrees C in 1 mbar 02, highlighting the markedly different reactivity of the two Cu2O surfaces. Annealing of the (100) surface, under ultrahigh vacuum conditions, to temperatures up to similar to 225 degrees C resulted in removal of the OH groups (0.46 ML decrease) at a rate similar to a detected increase in CuO coverage (0.45 ML increase), suggesting the reaction path 2OH(adsorbed) + CU2Osolid -> H2Ogas + 2CuO(solid). STM was used to correlate the observed changes in surface chemistry with surface morphology, confirming the surface hydroxylation and CuO formation. The STM analysis showed dramatic changes in surface morphology demonstrating a high mobility of the active species under reaction conditions., QC 20190123

Published
2018
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17. Unravelling the effect of charge dynamics at the plasmonic metal/semiconductor interface for CO2 photoreduction

Author

European Research Council, Ministerio de Economía y Competitividad (España), Coronado, Juan M. [0000-0003-1919-8371], Fresno, Fernando [0000-0001-6622-6721], de la Peña O’Shea, Víctor A. [0000-0001-5762-4787], Collado, Laura, Reynal, Anna, Fresno, Fernando, Barawi, Mariam, Escudero, Carlos, Perez-Dieste, Virginia, Coronado, Juan M., Serrano, David P., Durrant, James R., Peña O'Shea, Víctor A. de la, European Research Council, Ministerio de Economía y Competitividad (España), Coronado, Juan M. [0000-0003-1919-8371], Fresno, Fernando [0000-0001-6622-6721], de la Peña O’Shea, Víctor A. [0000-0001-5762-4787], Collado, Laura, Reynal, Anna, Fresno, Fernando, Barawi, Mariam, Escudero, Carlos, Perez-Dieste, Virginia, Coronado, Juan M., Serrano, David P., Durrant, James R., and Peña O'Shea, Víctor A. de la

Abstract

[EN] Sunlight plays a critical role in the development of emerging sustainable energy conversion and storage technologies. Light-induced CO2 reduction by artificial photosynthesis is one of the cornerstones to produce renewable fuels and environmentally friendly chemicals. Interface interactions between plasmonic metal nanoparticles and semiconductors exhibit improved photoactivities under a wide range of the solar spectrum. However, the photoinduced charge transfer processes and their influence on photocatalysis with these materials are still under debate, mainly due to the complexity of the involved routes occurring at different timescales. Here, we use a combination of advanced in situ and time-resolved spectroscopies covering different timescales, combined with theoretical calculations, to unravel the overall mechanism of photocatalytic CO2 reduction by Ag/TiO2 catalysts. Our findings provide evidence of the key factors determining the enhancement of photoactivity under ultraviolet and visible irradiation, which have important implications for the design of solar energy conversion materials.

Published
2018

18. Unravelling the effect of charge dynamics at the plasmonic metal/semiconductor interface for CO2 photoreduction.

Author

Collado, Laura, Reynal, Anna, Fresno, Fernando, Barawi, Mariam, Escudero, Carlos, Perez-Dieste, Virginia, Coronado, Juan M., Serrano, David P., Durrant, James R., and de la Peña O’Shea, Víctor A.

Abstract

Sunlight plays a critical role in the development of emerging sustainable energy conversion and storage technologies. Light-induced CO2 reduction by artificial photosynthesis is one of the cornerstones to produce renewable fuels and environmentally friendly chemicals. Interface interactions between plasmonic metal nanoparticles and semiconductors exhibit improved photoactivities under a wide range of the solar spectrum. However, the photo-induced charge transfer processes and their influence on photocatalysis with these materials are still under debate, mainly due to the complexity of the involved routes occurring at different timescales. Here, we use a combination of advanced in situ and time-resolved spectroscopies covering different timescales, combined with theoretical calculations, to unravel the overall mechanism of photocatalytic CO2 reduction by Ag/TiO2 catalysts. Our findings provide evidence of the key factors determining the enhancement of photoactivity under ultraviolet and visible irradiation, which have important implications for the design of solar energy conversion materials. Light-driven CO2 reduction provides a way to limit greenhouse gas concentrations, but understanding how materials accomplish this transformation is challenging. Here, authors examine the reaction over plasmonic silver-titanium dioxide using time-resolved, in situ techniques to follow the mechanism. [ABSTRACT FROM AUTHOR]

Published
2018
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