Abstract
We applied the quantum mechanics/fluctuating charges (QM/FQ) method to simulate the absorption spectra of three protonated forms of p-hydroxybenzylidene imidazolone (p-HBDI) in water. Configurations of solute-solvent were generated from molecular dynamics (MD) simulation within the context of a hybrid scheme in which solute and solvents were treated at QM and molecular mechanics, respectively. Nonperiodic spherical boundary condition was used. To examine the influence on simulated spectra coming from the geometrical relaxation of solute, the MD simulations were carried out for two cases: frozen and flexible molecular geometry of solute. As a result of our calculations, the simulations using the flexible solute's structure delivered vertical excitation energies closer to experimental data than those of a frozen solute, especially for the neutral case. For spectral broadening, changing from fixed geometry of solute to a flexible one led to a significant increase for both neutral and anionic forms of p-HBDI, but no effect happened for the cationic one.
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Lu, S. I., & Wang, B. C. (2023). Quantum mechanics/fluctuating charge calculations for absorption spectra of aqueous green fluorescent protein chromophore. Journal of the Chinese Chemical Society, 70(5), 1102–1107. https://doi.org/10.1002/jccs.202300053
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