Your search keyword '"Fisheries - recreational"' showing total 3 results

1. Quantum-Chemical Design of Cryptand-like Ditopic Salt Binders

Author

and Angelo J. Amoroso, David E. Hibbs, James Alexis Platts, Siân T. Howard, Howard, Sian, Hibbs, D, Amoroso, Angelo, and Platts, J

Subjects

Bicyclic molecule, Ligand, Mechanical Engineering, 030302 [FOR], Cryptand, Nanotechnology, Chloride, supramolecular design, Computer Science Applications, Ion, quantum chemistry, Crystallography, chemistry.chemical_compound, Nanochemistry and Supramolecular Chemistry, Thiourea, chemistry, 030701 [ASCED], medicine, Amine gas treating, Physical and Theoretical Chemistry, Binding site, Fisheries - recreational, medicine.drug

Abstract

Hartree-Fock, density functional, and MP2 methods are applied to the problem of designing neutral, bicyclic C3-symmetric cages incorporating interacting anion- and cation-binding sites which strongly bind NaCl as an ion contact pair. A large number of trial ligands L and their complexes L:NaCl are tested, with the focus on maximizing binding by (i) optimizing the cavity size and shape and (ii) varying the nature of the anion- and cation-binding functionalities. The corresponding complexes L:Cl(-) and L:Na(+) are also studied in some detail. An analysis of their structures and charge distributions helps to build a consistent picture of the requirements for a successful NaCl binding. The 'best' candidate ligand utilizes a tripodal triether-substituted amine N(CH2CH2OR-)3 to bind the sodium cation; three thiourea groups in a tripodal arrangement with a 1,3,5-trisubstituted benzyl spacer group {C6H3(CH2NHC [Formula: see text] XNH-)3 X=O,S} to bind chloride; and a -CH2CH2- spacer linking the two binding sites. A simple Quantitative Structure-Property analysis suggests that the binding cavity shape and size is near to the optimal one for this system.

Published

2006

2. Benzene physical and chemical organogels: Effect of network scaffolding on the thermodynamic behavior of entrapped solvent molecules

Author

Naba K. Dutta, Milena Ginic-Markovic, Novica Markovic, Dutta, Naba Kumar, Ginic-Markovic, Milena, and Markovic,Novica

Subjects

Materials science, crystallization, Polymers and Plastics, differential scanning calorimetry (DSC), nucleation, Population, Kinetics, organogels, network scaffolding, law.invention, Nanochemistry and Supramolecular Chemistry, Differential scanning calorimetry, law, Polymer chemistry, Materials Chemistry, Molecule, Crystallization, education, chemistry.chemical_classification, education.field_of_study, 030302 [FOR], General Chemistry, Polymer, self-organization, Surfaces, Coatings and Films, Solvent, Avrami equation, chemistry, Chemical engineering, Physical Sciences, Fisheries - recreational

Abstract

This paper presents a thermodynamic investigation of the benzene physical and chemical organogels, using differential scanning calorimetry (DSC) and intends to draw an appropriate relationship between the gel network structure and the properties. Physical gels, formed by an aluminium soap of fatty acid, and chemical gels, created by in situ cross-linking of a siloxane copolymer are investigated. The effects of the type and quantity of the gelators and their corresponding network mesh size distribution in the gels on crystallization, melting, and their kinetics are examined. It appears that the kinetics of crystallization of the entrapped solvent is significantly affected by the quality of the gel network scaffolding and can be treated successfully by the Avrami equation of crystallization. From the melting behavior of the entrapped solvent crystallites, quantitative information about the number of solvent molecules bound per molecule of the gelator has been extracted. DSC proves to be a reliable technique to evaluate the population distribution of solvent molecules trapped in the physical and chemical organogel network scaffolding. The state of the solvent may be treated as a probe to understand the structure of the gels. © 2004 Wiley Periodicals, Inc. J Appl Polym Sci 94: 1253–1264, 2004

Published

2004

3. Block copolymer directed nanocomposites for fuel cell applications

Author

Dermis,Terry, Mayavan,Sundar, Dutta, Naba Kumar, Choudhury, Namita Roy, Holdcroft, Steven, and Santa Clara, California 2007-05-23

Subjects

fuel cell, Nanochemistry and Supramolecular Chemistry, Synthesis of Materials, 030302 [FOR], electrocatalyst, block copolymer, nanoparticles, Materials Engineering, platinum, Fisheries - recreational, Physical Chemistry of Materials, self-organization

Published

2007