Temporal Electronic Structures of Nonresonant Raman Excited Virtual States of P-Hydroxybenzoic Acid

An algorithm is employed to calculate molecular bond polarizabilities of p-hydroxybenzoic acid, which supplies essential electronic information of the nonresonant Raman excited virtual states. The main dynamical behavior of the excited virtual states of p-hydroxybenzoic acid with 514.5nm excitation is such that the Raman excited electrons tend to flow to the C-C connected with -OH and -COOH from the benzene ring because of the electronic repulsion effect. The distribution of the electrons at the final stage of relaxation is given out through the comparison between the bond electronic densities of the ground states and the bond polarizabilities after de-excitation. Furthermore, the relaxation characteristic times of bond polarizabilities shows that the transport of electrons on -COOH is distinct.

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