Your search keyword '"López-Haro M"' showing total 8 results

1. Stability and Reversible Oxidation of Sub-Nanometric Cu 5 Metal Clusters: Integrated Experimental Study and Theoretical Modeling.

Author

Buceta D, Huseyinova S, Cuerva M, Lozano H, Giovanetti LJ, Ramallo-López JM, López-Caballero P, Zanchet A, Mitrushchenkov AO, Hauser AW, Barone G, Huck-Iriart C, Escudero C, Hernández-Garrido JC, Calvino JJ, López-Haro M, de Lara-Castells MP, Requejo FG, and López-Quintela MA

Abstract

Sub-nanometer metal clusters have special physical and chemical properties, significantly different from those of nanoparticles. However, there is a major concern about their thermal stability and susceptibility to oxidation. In situ X-ray Absorption spectroscopy and Near Ambient Pressure X-ray Photoelectron spectroscopy results reveal that supported Cu 5 clusters are resistant to irreversible oxidation at least up to 773 K, even in the presence of 0.15 mbar of oxygen. These experimental findings can be formally described by a theoretical model which combines dispersion-corrected DFT and first principles thermochemistry revealing that most of the adsorbed O 2 molecules are transformed into superoxo and peroxo species by an interplay of collective charge transfer within the network of Cu atoms and large amplitude "breathing" motions. A chemical phase diagram for Cu oxidation states of the Cu 5 -oxygen system is presented, clearly different from the already known bulk and nano-structured chemistry of Cu., (© 2023 The Authors. Chemistry - A European Journal published by Wiley-VCH GmbH.)

Published

2023

2. Confined Pt 1 1+ Water Clusters in a MOF Catalyze the Low-Temperature Water-Gas Shift Reaction with both CO 2 Oxygen Atoms Coming from Water.

Author

Rivero-Crespo MA, Mon M, Ferrando-Soria J, Lopes CW, Boronat M, Leyva-Pérez A, Corma A, Hernández-Garrido JC, López-Haro M, Calvino JJ, Ramos-Fernandez EV, Armentano D, and Pardo E

Abstract

The synthesis and reactivity of single metal atoms in a low-valence state bound to just water, rather than to organic ligands or surfaces, is a major experimental challenge. Herein, we show a gram-scale wet synthesis of Pt 1 1+ stabilized in a confined space by a crystallographically well-defined first water sphere, and with a second coordination sphere linked to a metal-organic framework (MOF) through electrostatic and H-bonding interactions. The role of the water cluster is not only isolating and stabilizing the Pt atoms, but also regulating the charge of the metal and the adsorption of reactants. This is shown for the low-temperature water-gas shift reaction (WGSR: CO + H 2 O → CO 2 + H 2 ), where both metal coordinated and H-bonded water molecules trigger a double water attack mechanism to CO and give CO 2 with both oxygen atoms coming from water. The stabilized Pt 1+ single sites allow performing the WGSR at temperatures as low as 50 °C., (© 2018 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

3. Synthesis of Densely Packaged, Ultrasmall Pt 0 2 Clusters within a Thioether-Functionalized MOF: Catalytic Activity in Industrial Reactions at Low Temperature.

Author

Mon M, Rivero-Crespo MA, Ferrando-Soria J, Vidal-Moya A, Boronat M, Leyva-Pérez A, Corma A, Hernández-Garrido JC, López-Haro M, Calvino JJ, Ragazzon G, Credi A, Armentano D, and Pardo E

Abstract

The gram-scale synthesis, stabilization, and characterization of well-defined ultrasmall subnanometric catalytic clusters on solids is a challenge. The chemical synthesis and X-ray snapshots of Pt 0 2 clusters, homogenously distributed and densely packaged within the channels of a metal-organic framework, is presented. This hybrid material catalyzes efficiently, and even more importantly from an economic and environmental viewpoint, at low temperature (25 to 140 °C), energetically costly industrial reactions in the gas phase such as HCN production, CO 2 methanation, and alkene hydrogenations. These results open the way for the design of precisely defined catalytically active ultrasmall metal clusters in solids for technically easier, cheaper, and dramatically less-dangerous industrial reactions., (© 2018 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

4. Chemical imaging at atomic resolution as a technique to refine the local structure of nanocrystals.

Author

Trasobares S, López-Haro M, Kociak M, March K, de la Peña F, Perez-Omil JA, Calvino JJ, Lugg NR, D'Alfonso AJ, Allen LJ, and Colliex C

Subjects

Cerium chemistry, Microscopy, Atomic Force, Oxygen chemistry, Particle Size, Zirconium chemistry, Nanoparticles chemistry

Published

2011

5. Fully reversible metal deactivation effects in gold/ceria-zirconia catalysts: role of the redox state of the support.

Author

Cíes JM, Del Río E, López-Haro M, Delgado JJ, Blanco G, Collins S, Calvino JJ, and Bernal S

Published

2010

6. Contributions of electron microscopy to understanding CO adsorption on powder Au/ceria-zirconia catalysts.

Author

Cíes JM, Delgado JJ, López-Haro M, Pilasombat R, Pérez-Omil JA, Trasobares S, Bernal S, and Calvino JJ

Abstract

The influence of the highly dispersed gold phase on the CO-support interaction occurring in two 2.5 wt % Au/Ce(0.62)Zr(0.38)O(2) catalysts with medium (Au/CZ-MD) and high (Au/CZ-HD) metal dispersion is quantitatively assessed. For this purpose, we have followed an approach in which high-angle annular dark-field scanning transmission electron microscopy (HAADF-STEM), computer modelling, volumetric adsorption and FTIR spectroscopy studies are combined. This approach has already been fruitfully applied to the investigation of the specific CO-metal adsorption in Au/ceria-zirconia catalysts. As deduced from the experimental studies reported herein, the presence of gold dramatically increases the amount of CO strongly chemisorbed on the support. Moreover, this amount is sensitive to the metal dispersion, thus suggesting the occurrence of a mechanism in which the CO molecules that are initially adsorbed on the gold nanoparticles are further transferred to the support by means of a spillover process. An annular model is proposed for the growth of the CO phase adsorbed on the ceria-zirconia mixed oxide in the presence of Au. By assuming this model, we have estimated the width of the annulus, Delta r, of the adsorbed CO grown around the Au nanoparticles in Au/CZ-MD and Au/CZ-HD catalysts. This value is found to be very close to Delta r approximately 2 nm in both cases, the coincidence lending some additional support to the model. To further confirm this proposal, we have investigated the influence of CO pre-adsorption on the D(2)-Au/CZ-MD interaction, at 298 K. As revealed by FTIR spectroscopy, the kinetics of the deuterium spillover is significantly disturbed by the pre-adsorbed CO, which is fully consistent with an annular model for the CO adsorption. We conclude from the global analysis of the results reported here and those already available on CO-Au adsorption that the appropriate combination of nanostructural, computer modelling and chemical techniques is a powerful tool allowing us to gain a comprehensive picture of the complex series of processes involved in the CO adsorption on this relevant family of gold catalysts.

Published

2010

7. Bridging the gap between CO adsorption studies on gold model surfaces and supported nanoparticles.

Author

López-Haro M, Delgado JJ, Cies JM, del Rio E, Bernal S, Burch R, Cauqui MA, Trasobares S, Pérez-Omil JA, Bayle-Guillemaud P, and Calvino JJ

Published

2010

8. 3 D characterization of gold nanoparticles supported on heavy metal oxide catalysts by HAADF-STEM electron tomography.

Author

González JC, Hernández JC, López-Haro M, del Río E, Delgado JJ, Hungría AB, Trasobares S, Bernal S, Midgley PA, and Calvino JJ

Abstract

Living on the edge: Three-dimensional reconstructions from electron tomography data recorded from Au/Ce(0.50)Tb(0.12)Zr(0.38)O(2-x) catalysts show that gold nanoparticles (see picture; yellow) are preferentially located on stepped facets and nanocrystal boundaries. An epitaxial relationship between the metal and support plays a key role in the structural stabilization of the gold nanoparticles.

Published

2009