Your search keyword '"Carlos Manuel Travieso"' showing total 5 results

1. Exploring the Nature of Wetting by Water of Surfaces of Alkane−Amidethiols Adsorbed on Gold Using the Electrostatic Potential Topology

Author

Carlos Manuel Travieso González, David Santiago Coll, Manuel Marquez, Yosslen Aray, and Jesus Rodriguez

Subjects

Alkane, chemistry.chemical_classification, Ab initio, Topology, Surfaces, Coatings and Films, Contact angle, Adsorption, chemistry, Materials Chemistry, Molecule, Density functional theory, Wetting, Physical and Theoretical Chemistry, Topology (chemistry)

Abstract

The nature of the interaction of water molecules with the surface of a set of experimentally well-studied alkane−amidethiols adsorbed on a gold(111) surface and its effect on the water contact angle have been studied by carrying out a systematic determination of the topology of electrostatic potential using ab initio density functional theory methods for periodic systems. The obtained results have shown that the water contact angle decreases systematically as the number of minima by surface cell unit and the electrostatic potential magnitude at these minima, and consequently the adsorption strength, increases. Thus, this electrostatic potential magnitude can be used as a measure of the efficiency and ability of a chemical group for wetting of a surface by water.

Published

2004

2. Electrostatics for Exploring the Nature of the Hydrogen Bonding in Polyethylene Oxide Hydration

Author

Yosslen Aray, David Vega, Santiago Coll, Manuel Marquez, David A. Weitz, Carlos Manuel Travieso González, Jesus Rodriguez, and Yamil Simón-Manso

Subjects

Ethylene oxide, Hydrogen bond, Electrostatics, Surfaces, Coatings and Films, chemistry.chemical_compound, Crystallography, chemistry, Computational chemistry, Helix, Materials Chemistry, Molecule, Density functional theory, Physical and Theoretical Chemistry, Lone pair, Topology (chemistry)

Abstract

Binding between water and models of poly(ethylene oxide), (CH2−CH2−O)n, n = 2−40, has been studied using the topographic features of the electrostatic potential, V(r), and standard density functional theory methods. It was found that, in general, the contour around the minima of the oxygen atoms overlap forming a negative-valued spiral coiled around a positive-valued helix. The positive zone defines a helical groove in the O−C−C−O units where minima lone pairs critical points are located. Topological analysis of the water molecule has also suggested that the attractive electrostatic effect between the positive water O−H zone and the negative PEO lone pairs plays an important role in the hydrogen bonding of the PEO−water system. Thus, the V(r) topology predicts a coil of water molecules around the PEO chain forming hydrogen bonding with two sites of ether oxygens. This coil is formed in such a way that more water molecules accumulate on the cavities surrounding the poly(ethylene oxide)'s oxygen atoms where...

Published

2004

3. Electrostatics for Exploring the Nature of Water Adsorption on the Laponite Sheets' Surface

Author

Santiago Coll, David A. Weitz, Jesus Rodriguez, Yosslen Aray, Carlos Manuel Travieso González, Yamil Simón-Manso, and Manuel Marquez

Subjects

Surface (mathematics), Work (thermodynamics), Chemistry, Electrostatics, Surfaces, Coatings and Films, Condensed Matter::Soft Condensed Matter, Adsorption, Chemical physics, Computational chemistry, Materials Chemistry, Molecule, Density functional theory, Physics::Chemical Physics, Physical and Theoretical Chemistry, Lone pair, Topology (chemistry)

Abstract

In this work, the topology of the electrostatic potential using density functional theory for periodic systems was used to study the nature of the interaction of water with laponite surfaces; an uncharged sheet model was also used. The topological analysis predicts that for uncharged surfaces the adsorption mode is such that the water molecules are adsorbed almost parallel to the surface. For laponite surfaces, where there is a net charge, the adsorption mode involves electrostatic repulsion between the negative lone pairs on the water molecules and the ones on the surface oxygen atoms. As a consequence, the water molecules bind to the surface in a perpendicular and tilted approach, minimizing the repulsive interactions. The advantage of using the topology of the electrostatic potential as an efficient method to describe the electrostatic interactions between adsorbates and surfaces is also discussed.

Published

2003

4. Coverage effects and the nature of the metal-sulfur bond in S/Au(111): high-resolution photoemission and density-functional studies

Author

Yosslen Aray, Gang Liu, Tomas Jirsak, Jan Hrbek, Joseph Dvorak, Carlos Manuel Travieso González, and José A. Rodriguez

Subjects

Stereochemistry, chemistry.chemical_element, General Chemistry, Electronic structure, Biochemistry, Sulfur, Catalysis, Metal, Colloid and Surface Chemistry, Adsorption, chemistry, Chemical bond, Transition metal, Chemical physics, visual_art, visual_art.visual_art_medium, Crystallite, Local-density approximation

Abstract

The bonding of sulfur to surfaces of gold is an important subject in several areas of chemistry, physics, and materials science. Synchrotron-based high-resolution photoemission and first-principles density-functional (DF) slab calculations were used to study the interaction of sulfur with a well-defined Au(111) surface and polycrystalline gold. Our experimental and theoretical results show a complex behavior for the sulfur/Au(111) interface as a function of coverage and temperature. At small sulfur coverages, the adsorption of S on fcc hollow sites of the gold substrate is energetically more favorable than adsorption on bridge or a-top sites. Under these conditions, S behaves as a weak electron acceptor but substantially reduces the density-of-states that gold exhibits near the Fermi edge. As the sulfur coverage increases, there is a weakening of the Au-S bonds (with a simultaneous reduction in the Au --S charge transfer and a modification in the S sp hybridization) that facilitates changes in adsorption site and eventually leads to S-S bonding. At sulfur coverages above 0.4 ML, S(2) and not atomic S is the more stable species on the gold surface. Formation of S(n)(n2) species occurs at sulfur coverages higher than a monolayer. Very similar trends were observed for the adsorption of sulfur on polycrystalline surfaces of gold. The S atoms bonded to Au(111) display a unique mobility/reactivity not seen on surfaces of early or late transition metals.

Published

2003

5. Rapid Fixation of Methylene Chloride by a Macrocyclic Amine

Author

Manuel Marquez, Jung-Jae Lee, Bruce C. Noll, Carlos Manuel Travieso González, Keith J. Stanger, and Bradley D. Smith

Subjects

chemistry.chemical_classification, Tertiary amine, Inorganic chemistry, Salt (chemistry), General Chemistry, Alkylation, Biochemistry, Chloride, Catalysis, Solvent, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Polymer chemistry, medicine, Amine gas treating, Ammonium chloride, Methylene, medicine.drug

Abstract

A simple macrocyclic amine is alkylated by methylene chloride to give a quaternary ammonium chloride salt. When methylene chloride is the solvent, the reaction exhibits pseudo-first-order kinetics, and the reaction half-life at 25.0 degrees C is 2.0 min. The reaction half-life for a structurally related, acyclic amine is approximately 50 000 times longer. Detailed calculations favor a mechanism where the methylene chloride associates with the macrocycle to form an activated prereaction complex. The macrocyclic nitrogen subsequently attacks the methylene chloride with a classic SN2 trajectory, and although the carbon-chlorine bond breaks, the chloride leaving group does not separate from the newly formed cationic macrocycle, such that the product is a tightly associated ion-pair. X-ray crystal structures of the starting amine and the product salt, as well as kinetic data, support this mechanism.

Published

2005