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  • 1
    Electronic Resource
    Electronic Resource
    Controlling the Future of Matter (1995)
    s.l. : American Chemical Society
    Accounts of chemical research 28 (1995), S. 133-140 
    Details
    ISSN: 1520-4898
    Source: ACS Legacy Archives
    Topics: Chemistry and Pharmacology
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1021/ar00051a006
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  • 2
    Electronic Resource
    Electronic Resource
    Activation to the transition state: reactant and solvent energy flow for a model SN2 reaction in water (1991)
    s.l. : American Chemical Society
    Journal of the American Chemical Society 113 (1991), S. 74-87 
    Details
    ISSN: 1520-5126
    Source: ACS Legacy Archives
    Topics: Chemistry and Pharmacology
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1021/ja00001a014
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  • 3
    Electronic Resource
    Electronic Resource
    Energy flow in an atom exchange chemical reaction in solution (1990)
    s.l. : American Chemical Society
    Journal of the American Chemical Society 112 (1990), S. 524-530 
    Details
    ISSN: 1520-5126
    Source: ACS Legacy Archives
    Topics: Chemistry and Pharmacology
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1021/ja00158a008
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  • 4
    Electronic Resource
    Electronic Resource
    Rate of Thermal Isomerization of cis-Butene-2 (1958)
    s.l. : American Chemical Society
    Journal of the American Chemical Society 80 (1958), S. 2384-2386 
    Details
    ISSN: 1520-5126
    Source: ACS Legacy Archives
    Topics: Chemistry and Pharmacology
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1021/ja01543a011
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  • 5
    Electronic Resource
    Electronic Resource
    Reaction dynamics from liquid structure (1991)
    College Park, Md. : American Institute of Physics (AIP)
    The Journal of Chemical Physics 95 (1991), S. 2458-2464 
    Details
    ISSN: 1089-7690
    Source: AIP Digital Archive
    Topics: Physics , Chemistry and Pharmacology
    Notes: The possible connection between the equilibrium structure of a solution and the chemical reaction dynamics that occur in that solution has been discussed by Adelman and co-workers. In this work, we present a computational demonstration of this connection using molecular dynamics simulations and the generalized Langevin equation (GLE). A favorable example of a reaction loosely based on thermally activated Cl+Cl2→Cl2+Cl in argon solvent is used for this demonstration by (1) computing equilibrium solution structural information in terms of the Ar–Ar and Ar–Cl radial distribution functions, both from integral equations and from molecular dynamics; (2) deriving a memory function for Cl in argon solvent from the radial distribution functions and the Ar–Cl potential; and (3) using this memory function in a simple GLE to compute the dynamics of the reaction. Energy flow results both for climbing and descending the barrier are in gratifying agreement with the dynamics of the same reaction as computed by full deterministic molecular dynamics.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1063/1.461802
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  • 6
    Electronic Resource
    Electronic Resource
    What can gas phase reactions tell us about solution reactions? (1990)
    College Park, Md. : American Institute of Physics (AIP)
    The Journal of Chemical Physics 93 (1990), S. 8821-8827 
    Details
    ISSN: 1089-7690
    Source: AIP Digital Archive
    Topics: Physics , Chemistry and Pharmacology
    Notes: Much of the behavior of simple gas phase reaction dynamics can be understood in terms of simple pictures based on the shapes of the underlying potential energy surfaces and the masses of the reagent atoms. Our aim here is to investigate to what extent such gas phase models can be used to understand properties of solution reactions. In particular, we examine for a solution reaction the validity of the Evans–Polanyi rule that an early potential barrier favors translational excitation of the reactants and vibrational excitation of the products, with the converse holding true for a late barrier. The test is performed by using molecular dynamics simulations for an asymmetric linear transition state A+BC→AB+C atom exchange reaction in argon solvent. We calculate for both gas and solution reactions the partitioning among translational, rotational, and vibrational energy during the reaction process. We find that for a short time period (−65 to 65 fs where t=0 is at the barrier top), in which the forces from the intrinsic gas phase potential dominate, the Evans–Polanyi rule can be carried over into the solution reaction. The gas phase vibrational energy distributions persist in solution over a much longer period. In particular, this calculation illustrates for an early barrier linear transition state potential in solution that a solvent induced fluctuation in the reagent translational energy is considerably more effective than a fluctuation in vibrational energy in prompting reaction. The resulting reaction products are formed highly vibrationally excited. For the reverse late barrier reaction, a solvent induced fluctuation in vibrational energy is needed for reaction and the resulting products are initially highly translationally excited. We expect that on the proper time scale, many other gas phase reaction dynamics rules will also carry over to solution reactions, particularly in cases in which the reagent–solvent interaction is weak.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1063/1.459220
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  • 7
    Electronic Resource
    Electronic Resource
    Nonequilibrium solvation effects on reaction rates for model SN2 reactions in water (1989)
    College Park, Md. : American Institute of Physics (AIP)
    The Journal of Chemical Physics 90 (1989), S. 3537-3558 
    Details
    ISSN: 1089-7690
    Source: AIP Digital Archive
    Topics: Physics , Chemistry and Pharmacology
    Notes: Molecular dynamics (MD) simulations of the model SN2 reaction Cl−+CH3Cl→ClCH3+Cl− in water, and variants thereof, are presented. The resulting transmission coefficients κ, that measure the deviations of the rates from the transition state theory (TST) rate predictions due to solvent-induced recrossings, are used to assess the validity of the generalized Langevin equation (GLE)-based Grote–Hynes (GH) theory. The GH predictions are found to agree with the MD results to within the error bars of the calculations for each of the 12 cases examined. This agreement extends from the nonadiabatic regime, where solvent molecule motions are unimportant and κ is determined by static solvent configurations at the transition state, into the polarization caging regime, where solvent motion is critical in determining κ. In contrast, the Kramers theory predictions for κ fall well below the simulation results. The friction kernel in the GLE used to evaluate the GH κ values is determined, from MD simulation, by a fixed-particle time correlation function of the force at the transition state. When this is expressed as a (Fourier) friction spectrum in frequency, marked similarities to the pure solvent spectrum are observed, and are used to identify the water solvent motions that determine the transmission coefficient κ. The deviations of κ from unity, the TST value, are dominated by solvent motions (translational and reorientational) which on the time scale of the recrossings are essentially static configurations. The deviations from the frozen solvent, nonadiabatic limit values κNA are dominated by the hinderd rotations (librations). Finally, the underlying assumptions of the GLE and the GH theory are discussed within the context of the simulation results.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1063/1.455864
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  • 8
    Electronic Resource
    Electronic Resource
    Molecular dynamics of a model SN2 reaction in water (1987)
    College Park, Md. : American Institute of Physics (AIP)
    The Journal of Chemical Physics 86 (1987), S. 1356-1376 
    Details
    ISSN: 1089-7690
    Source: AIP Digital Archive
    Topics: Physics , Chemistry and Pharmacology
    Notes: Molecular dynamics are computed for a model SN2 reaction Cl−+CH3Cl→ClCH3+Cl− in water and are found to be strongly dependent on the instantaneous local configuration of the solvent at the transition state barrier. There are significant deviations from the simple picture of passage over a free energy barrier in the reaction coordinate, and thus, a marked departure from transition state theory occurs in the form of barrier recrossings. Factors controlling the dynamics are discussed, and, in particular, the rate of change of atomic charge distribution along the reaction coordinate is found to have a major effect on the dynamics. A simple frozen solvent theory involving nonadiabatic solvation is presented which can predict the outcome of a particular reaction trajectory by considering only the interaction with the solvent of the reaction system at the gas-phase transition barrier. The frozen solvent theory also gives the transmission coefficient κ needed to make the transition state theory rate agree with the outcome of the molecular dynamics trajectories. This theoretical κ value, which is the implementation for the SN2 reaction of the van der Zwan–Hynes nonadiabatic solvation transmission coefficient, is in good agreement with the trajectory results. In contrast, a Kramers theory description fails dramatically.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1063/1.452224
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  • 9
    Electronic Resource
    Electronic Resource
    Nonadiabatic solvation model for SN2 reactions in polar solvents (1987)
    College Park, Md. : American Institute of Physics (AIP)
    The Journal of Chemical Physics 86 (1987), S. 1377-1386 
    Details
    ISSN: 1089-7690
    Source: AIP Digital Archive
    Topics: Physics , Chemistry and Pharmacology
    Notes: An analytic theory for SN2 reactions in polar solvents in the nonadiabatic solvation limit is presented and used to interpret the computer simulation results of the preceding paper by Bergsma et al. The theory is based on the nonadiabatic solvation limit of previous studies by van der Zwan and Hynes and incorporates the solvent approximately but explicitly via a coordinate additional to the intrinsic reaction coordinate. Central results include: an explicit expression for the reaction transmission coefficient κ, the dependence of reaction probability on kinetic energy, the interpretation of κ in terms of nonequilibrium solvation entropy effects, and the deviation of the reaction coordinate from that assumed in the standard equilibrium solvation transition state theory view of the reaction.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1063/1.452225
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  • 10
    Electronic Resource
    Electronic Resource
    Proposed experimental probes of chemical reaction molecular dynamics in solution: ICN photodissociation (1989)
    College Park, Md. : American Institute of Physics (AIP)
    The Journal of Chemical Physics 90 (1989), S. 4176-4197 
    Details
    ISSN: 1089-7690
    Source: AIP Digital Archive
    Topics: Physics , Chemistry and Pharmacology
    Notes: Knowledge of how translational and rotational motions are influenced by the solvent during the course of a photodissociation "half-collision'' reaction in solution is of interest in itself and can also help our understanding of how thermally activated reactions take place in solution by means of fluctuations in translational and rotational motion. With this goal, the molecular dynamics of the photodissociation of the triatomic molecule ICN are compared in the gas phase and in Xe solution. The time evolution of the trajectories (particularly with respect to interfragment distance and CN orientation) and of the energy partitioning (particularly into fragment translational recoil and into rotation of the CN) are displayed. Two types of solution experiments are proposed and simulated, both closely related to recent gas phase studies by Dantus, Rosker, and Zewail. These experiments are designed to probe the detailed dynamics of chemical reactions in solution during the time period the reaction is in progress, in particular to reveal the dramatic effects of the solvent on translational motions and energies. Both are pump–probe experiments in which the first photon dissociates the ICN and the second induces fluorescence in the CN fragment. In the first type of experiment, which is particularly sensitive to fragment translational motion, the fluorescence intensity is measured as a function of photon energy and of time delay. In the second type of experiment, which is particularly sensitive to fragment rotation, in addition the angle between the polarizations of the pump and probe photons is varied. In the calculations presented here, the effect of the absorption of the photodissociation photon is treated using the classical Frank–Condon principle. The coupling between the assumed two upper electronic surfaces is taken into account semiclassically using a generalization to the condensed phase of the classical electron model of Miller and Meyer, which was applied to ICN photodissociation in the gas phase by Goldfield, Houston, and Ezra.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1063/1.455775
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