Abstract

The photochemical reaction of potassium ferrocyanide (K4Fe(CN)6) exhibits excitation wavelength dependence and non-Kasha rule behavior. In this study, the excited-state dynamics of K4Fe(CN)6 were studied by transient absorption spectroscopy. Excited state electron detachment (ESED) and photoaquation reactions were clarified by comparing the results of 260, 320, 340, and 350 nm excitations. ESED is the path to generate a hydrated electron (eaq−). ESED energy barrier varies with the excited state, and it occurs even at the first singlet excited state (1T1g). The 1T1g state shows ∼0.2 ps lifetime and converts into triplet [Fe(CN)6]4− by intersystem crossing. Subsequently, 3[Fe(CN)5]3− appears after one CN− ligand is ejected. In sequence, H2O attacks [Fe(CN)5]3− to generate [Fe(CN)5H2O]3− with a time constant of approximately 20 ps. The 1T1g state and eaq− exhibit strong reducing power. The addition of uridine 5′-monophosphate (UMP) to the K4Fe(CN)6 solution decrease the yield of eaq− and reduce the lifetimes of the eaq− and 1T1g state. The obtained reaction rate constant of 1T1g state and UMP is 1.7×1014 (mol/L)−1·s−1, and the eaq− attachment to UMP is ∼8×109 (mol/L)−1·s−1. Our results indicate that the reductive damage of K4Fe(CN)6 solution to nucleic acids under ultraviolet irradiation cannot be neglected.

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