The free energy profile and the (classical) kinetics of chemical reactions in (soft) condensed phase are modeled theoretically by means of molecular dynamics simulations, the Perturbed Matrix Method (PMM) and the quasi Gaussian entropy (QGE) theory. In this paper we describe the theoretical framework and apply the model to the intramolecular proton transfer reaction of aqueous malonaldehyde. Although in the present application we disregard the quantum effects for the proton dynamics along the reaction coordinate (i.e., tunneling), the classical-like view of the proton transition over the reaction free energy surface seems to properly describe the kinetic process and shows that water acts lowering the reaction free energy barrier. Moreover, a weak temperature dependence of the free energy surface is obtained, implying small entropy variations in the transition. Interestingly the activation entropy, as provided by the QGE model, is negative in the whole temperature range considered, thus indicating an entropy reduction at the transition structure. Finally, by comparing our results with theoretical and experimental literature data, we critically address the actual role of tunneling in this reaction and discuss the emerging kinetic scheme. Copyright (c) 2006 John Wiley & Sons, Ltd.

Theoretical modeling of chemical reactions in complex environments: The intramolecular proton transfer in aqueous malonaldehyde / Aschi, Massimiliano; D'Abramo, Marco; Ramondo, Fabio; Daidone, Isabella; D'Alessandro, Maira; DI NOLA, Alfredo; Amadei, Andrea. - In: JOURNAL OF PHYSICAL ORGANIC CHEMISTRY. - ISSN 0894-3230. - STAMPA. - 19:8-9(2006), pp. 518-530. (Intervento presentato al convegno 10th European Symposium on Organic Reactivity ( ESOR-10) tenutosi a Rome, ITALY nel JUL, 2005) [10.1002/poc.1051].

Theoretical modeling of chemical reactions in complex environments: The intramolecular proton transfer in aqueous malonaldehyde

ASCHI, Massimiliano;D'ABRAMO, Marco;DAIDONE, Isabella;D'ALESSANDRO, Maira;DI NOLA, Alfredo;AMADEI, andrea
2006

Abstract

The free energy profile and the (classical) kinetics of chemical reactions in (soft) condensed phase are modeled theoretically by means of molecular dynamics simulations, the Perturbed Matrix Method (PMM) and the quasi Gaussian entropy (QGE) theory. In this paper we describe the theoretical framework and apply the model to the intramolecular proton transfer reaction of aqueous malonaldehyde. Although in the present application we disregard the quantum effects for the proton dynamics along the reaction coordinate (i.e., tunneling), the classical-like view of the proton transition over the reaction free energy surface seems to properly describe the kinetic process and shows that water acts lowering the reaction free energy barrier. Moreover, a weak temperature dependence of the free energy surface is obtained, implying small entropy variations in the transition. Interestingly the activation entropy, as provided by the QGE model, is negative in the whole temperature range considered, thus indicating an entropy reduction at the transition structure. Finally, by comparing our results with theoretical and experimental literature data, we critically address the actual role of tunneling in this reaction and discuss the emerging kinetic scheme. Copyright (c) 2006 John Wiley & Sons, Ltd.
2006
chemical kinetics; molecular dynamics; quantum mechanics; statistical mechanics
01 Pubblicazione su rivista::01a Articolo in rivista
Theoretical modeling of chemical reactions in complex environments: The intramolecular proton transfer in aqueous malonaldehyde / Aschi, Massimiliano; D'Abramo, Marco; Ramondo, Fabio; Daidone, Isabella; D'Alessandro, Maira; DI NOLA, Alfredo; Amadei, Andrea. - In: JOURNAL OF PHYSICAL ORGANIC CHEMISTRY. - ISSN 0894-3230. - STAMPA. - 19:8-9(2006), pp. 518-530. (Intervento presentato al convegno 10th European Symposium on Organic Reactivity ( ESOR-10) tenutosi a Rome, ITALY nel JUL, 2005) [10.1002/poc.1051].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11573/18439
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