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Model site

Jin X, Wang NHL, Tarjus G and Talbot J 1993 Irreversible adsorption on nonuniform surfaoes the random site model J. Phys. Chem. 97 4256-8... [Pg.2852]

The range of systems that have been studied by force field methods is extremely varied. Some force fields liave been developed to study just one atomic or molecular sp>ecies under a wider range of conditions. For example, the chlorine model of Rodger, Stone and TUdesley [Rodger et al 1988] can be used to study the solid, liquid and gaseous phases. This is an anisotropic site model, in which the interaction between a pair of sites on two molecules dep>ends not only upon the separation between the sites (as in an isotropic model such as the Lennard-Jones model) but also upon the orientation of the site-site vector with resp>ect to the bond vectors of the two molecules. The model includes an electrostatic component which contciins dipwle-dipole, dipole-quadrupole and quadrupole-quadrupole terms, and the van der Waals contribution is modelled using a Buckingham-like function. [Pg.249]

PRISM (polymer reference interaction-site model) method for modeling homopolymer melts... [Pg.367]

Fig. 2. Two-site models of the sonochemical reactioas sites, (a) Thermal diffusioa sheU model (b) surface wave droplet model. Fig. 2. Two-site models of the sonochemical reactioas sites, (a) Thermal diffusioa sheU model (b) surface wave droplet model.
PLE catalyzes the hydrolysis of a wide range of meso-diesters (Table 2). This reaction is interesting from both theoretical and practical standpoints. Indeed, the analysis of a large range of kinetic data provided sufficient information to create a detailed active site model of PLE (31). From a practical standpoint, selective hydrolysis of y j (9-cyclo-I,2-dicarboxylates leads to chiral synthons that are valuable intermediates for the synthesis of a variety of natural products. [Pg.333]

Heterogeneity Adsorbents and ion exchangers can be physically and chemically heterogeneous. Although exceptions exist, solutes generally compete for the same sites. Models for adsorbent heterogeneity have been developed for both discrete and continuous distributions of energies [Ross and Olivier, On Physical Adsorption, Interscience, New York, 1964 Jaroniec and Madey, Rudzinsld and Everett, gen. refs.]. [Pg.1504]

One important class of integral equation theories is based on the reference interaction site model (RISM) proposed by Chandler [77]. These RISM theories have been used to smdy the confonnation of small peptides in liquid water [78-80]. However, the approach is not appropriate for large molecular solutes such as proteins and nucleic acids. Because RISM is based on a reduction to site-site, solute-solvent radially symmetrical distribution functions, there is a loss of infonnation about the tliree-dimensional spatial organization of the solvent density around a macromolecular solute of irregular shape. To circumvent this limitation, extensions of RISM-like theories for tliree-dimensional space (3d-RISM) have been proposed [81,82],... [Pg.144]

LG Boulu, GM Crippen. Voronoi binding site models Calculation of binding models and influence of drag binding data accuracy. I Comput Chem 10(5) 673-682, 1989. [Pg.367]

The integral equation method is free of the disadvantages of the continuum model and simulation techniques mentioned in the foregoing, and it gives a microscopic picture of the solvent effect within a reasonable computational time. Since details of the RISM-SCF/ MCSCF method are discussed in the following section we here briefly sketch the reference interaction site model (RISM) theory. [Pg.419]

Upon completion of both the preliminary and detailed site investigation, a conceptual model can be prepared. A conceptual model is essentially a site model which includes all of the information that has been acquired for the site from both preliminary and detailed investigations, as well as other investigations not directly related to the site. The conceptual model can be anything from simple diagrams to detailed computer simulations, depending ujran the complexity of the site. The model must be continually updated to include new information as it is developed. [Pg.129]

FIG. 5 Schematic of site parameters and interactions employed for the hollow-bridge site model of Te on W(IOO). Also depicted are the six hollow sites (squares) and adjacent bridge sites (small open circles) allowed in one strip in the construction of the transfer matrix. (Reprinted from Ref. 37 with permission from Elsevier Science.)... [Pg.457]

In view of the importance of water in chemistry and biology, there have been many attempts to construct simple yet effective intramolecular potentials for water molecules. Water monomers are traditionally left rigid. The early three-site model for water took positive charges on the hydrogens ( h) and a negative charge (qo = on the oxygen, and wrote the pair potential between two... [Pg.67]

A. Two site model with two equivalent non-interacting binding sites. Kb = 1.2 M 1, koff = 6.6x10 7 sec, kcb = 1.3 x 107/sec. This model is incorrect because a tight and a weak site have been observed with different off-rate constants as listed in part B. [Pg.193]

This equation gives (0) = 0, a maximum at =. /Km/K2, and (oo) = 0. The assumed mechanism involves a first-order surface reaction with inhibition of the reaction if a second substrate molecule is adsorbed. A similar functional form for (s) can be obtained by assuming a second-order, dual-site model. As in the case of gas-solid heterogeneous catalysis, it is not possible to verify reaction mechanisms simply by steady-state rate measurements. [Pg.438]

Solution This case is different than any previously considered site models since product can be formed by two distinct reactions. [Pg.439]

One component obeys the Bemoullian model the other two obey the enantiomorphic- site model. Similarly, the NMR data of fractionated copolymers can be used to demonstrate the presence of multiple components in the copolymers. An example is shown of ethylene-propylene copolymers where the NMR/fractionation data are used to show the presence of two or three catalytic sites. [Pg.174]

Note that it is not possible in this case to carry out the three-site analysis on the whole-polymer HMR data alone. There are only eight known values (the eight pentads) and seven parameters. Mathematically, it is therefore difficult to apply the three-site model. Fractionation data have to be used. [Pg.180]

In order to test higher-order or multi-site models, it is preferable to study HMR data of polymer fractions. In this work, we shall use the pairwise HMR/fractions data to fit to multi-site models. This Is carried out in the same way as in the pairwise fraction on the tactlcity data. We can either use the two-state B/B model, or even three-state B/B/B model If applicable. The comonomer sequence intensity data for the two fractions are entered Into the computer. A total of 12 entries are Involved (6 for each fraction). The equations for the three-state copolymer... [Pg.184]

Fig. 3.11 Alkylating polyamide binding site model and structures of polyamide-alkylator conjugates. The dotted triangle represents the alkylating agent. All other symbols are defined in Fig. 3.4. The CBI and chlorambucil alkylator domains are boxed... Fig. 3.11 Alkylating polyamide binding site model and structures of polyamide-alkylator conjugates. The dotted triangle represents the alkylating agent. All other symbols are defined in Fig. 3.4. The CBI and chlorambucil alkylator domains are boxed...
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See also in sourсe #XX -- [ Pg.208 , Pg.223 , Pg.269 ]



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