P. Bado, P. H. Berens, J. Bergsma, M. Coladonato, C. Dupuy
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Molecular Dynamics of Chemical Reactions in Solution
We hope to answer one of the most fundamental and important unsolved questions
in chemistry: how, from a molecular perspective, do chemical reactions in solution
actually occur. The key to solving this long-standing problem is to understand the
molecular dynamics, i.e., the motions of the atoms and the forces that drive them. We
have already developed theoretical techniques and computational procedures involving
specialized computer hardware needed to calculate the molecular dynamics for many
chemical reactions in solution. From the dynamics we have derived the interface for
experimental verification, namely transient electronic, infrared, and Raman spectra as
well as X-ray diffraction, all of which are potentially observable manifestations of the
atomic motions during the reaction. We have tested our approach on the simple
inorganic I2 photodissociation and solvent caging reaction. The agreement between
molecular dynamics based theory and experimental picosecond transient electronic
absorption spectrum as a function of solvent, time, and wavelength is sufficiently close
as to indicate that for the first time we are discovering at least part of the molecular
dynamics by which a real solution chemical reaction takes place.
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