Abstract
We present condensed-phase first-principles molecular dynamics simulations to elucidate the presence of different electron trapping sites in liquid methanol and their roles in the formation, electronic transitions, and relaxation of solvated electrons (emet−) in methanol. Excess electrons injected into liquid methanol are most likely trapped by methyl groups, but rapidly diffuse to more stable trapping sites with dangling OH bonds. After localization at the sites with one free OH bond (1OH trapping sites), reorientation of other methanol molecules increases the OH coordination number and the trap depth, and ultimately four OH bonds become coordinated with the excess electrons under thermal conditions. The simulation identified four distinct trapping states with different OH coordination numbers. The simulation results also revealed that electronic transitions of emet− are primarily due to charge transfer between electron trapping sites (cavities) formed by OH and methyl groups, and that these transitions differ from hydrogenic electronic transitions involving aqueous solvated electrons (eaq−). Such charge transfer also explains the alkyl-chain-length dependence of the photoabsorption peak wavelength and the excited-state lifetime of solvated electrons in primary alcohols.
Highlights
Since solvated electrons were spectroscopically identi ed in the 1960s, they have attracted much attention as prototypical free radicals and the most fundamental reducing reagents in solutions.[1,2] They play crucial roles in ionization, charge transfer, and redox processes in solutions, and potentially cause radiation damage of biological systems.[3]
We present condensed-phase first-principles molecular dynamics simulations to elucidate the presence of different electron trapping sites in liquid methanol and their roles in the formation, electronic transitions, and relaxation of solvated electrons in methanol
The simulation results revealed that electronic transitions of emetÀ are primarily due to charge transfer between electron trapping sites formed by OH and methyl groups, and that these transitions differ from hydrogenic electronic transitions involving aqueous solvated electrons
Summary
Since solvated electrons (esolÀ) were spectroscopically identi ed in the 1960s, they have attracted much attention as prototypical free radicals and the most fundamental reducing reagents in solutions.[1,2] They play crucial roles in ionization, charge transfer, and redox processes in solutions, and potentially cause radiation damage of biological systems.[3]. Since solvated electrons (esolÀ) were spectroscopically identi ed in the 1960s, they have attracted much attention as prototypical free radicals and the most fundamental reducing reagents in solutions.[1,2]. They play crucial roles in ionization, charge transfer, and redox processes in solutions, and potentially cause radiation damage of biological systems.[3]. Owing to their short lifetimes and low concentrations, experimental determination of their geometrical structures using electron/Xray diffraction or nuclear magnetic resonance has been difficult. A detailed study on the structure and dynamics of esolÀ in alcohols may contribute to developing highly efficient and environmentally benign reduction reactions.[9–11]
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