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15. 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

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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19. Stabilization of the Active Ruthenium Oxycarbonate Phase for Low-Temperature CO 2 Methanation.

Author

Tébar-Soler C, Diaconescu VM, Simonelli L, Missyul A, Perez-Dieste V, Villar-García I, Gómez D, Brubach JB, Roy P, Corma A, and Concepción P

Abstract

Interstitial carbon-doped RuO 2 catalyst with the newly reported ruthenium oxycarbonate phase is a key component for low-temperature CO 2 methanation. However, a crucial factor is the stability of interstitial carbon atoms, which can cause catalyst deactivation when removed during the reaction. In this work, the stabilization mechanism of the ruthenium oxycarbonate active phase under reaction conditions is studied by combining advanced operando spectroscopic tools with catalytic studies. Three sequential processes: carbon diffusion, metal oxide reduction, and decomposition of the oxycarbonate phase and their influence by the reaction conditions, are discussed. We present how the reaction variables and catalyst composition can promote carbon diffusion, stabilizing the oxycarbonate catalytically active phase under steady-state reaction conditions and maintaining catalyst activity and stability over long operation times. In addition, insights into the reaction mechanism and a detailed analysis of the catalyst composition that identifies an adequate balance between the two phases, i.e., ruthenium oxycarbonate and ruthenium metal, are provided to ensure an optimum catalytic behavior., Competing Interests: The authors declare no competing financial interest., (© 2024 The Authors. Published by American Chemical Society.)

Published
2024
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20. Low-oxidation-state Ru sites stabilized in carbon-doped RuO 2 with low-temperature CO 2 activation to yield methane.

Author

Tébar-Soler C, Martin-Diaconescu V, Simonelli L, Missyul A, Perez-Dieste V, Villar-García IJ, Brubach JB, Roy P, Haro ML, Calvino JJ, Concepción P, and Corma A

Abstract

The generation of methane fuel using surplus renewable energy with CO 2 as the carbon source enables both the decarbonization and substitution of fossil fuel feedstocks. However, high temperatures are usually required for the efficient activation of CO 2 . Here we present a solid catalyst synthesized using a mild, green hydrothermal synthesis that involves interstitial carbon doped into ruthenium oxide, which enables the stabilization of Ru cations in a low oxidation state and a ruthenium oxycarbonate phase to form. The catalyst shows an activity and selectivity for the conversion of CO 2 into methane at lower temperatures than those of conventional catalysts, with an excellent long-term stability. Furthermore, this catalyst is able to operate under intermittent power supply conditions, which couples very well with electricity production systems based on renewable energies. The structure of the catalyst and the nature of the ruthenium species were acutely characterized by combining advanced imaging and spectroscopic tools at the macro and atomic scales, which highlighted the low-oxidation-state Ru sites (Ru n+ , 0 < n < 4) as responsible for the high catalytic activity. This catalyst suggests alternative perspectives for materials design using interstitial dopants., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published
2023
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