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Impact of the Dynamic Electron Correlation on the Unusually Long Excited-State Lifetime of Thymine

Woojin Park, Seunghoon Lee, Miquel Huix‐Rotllant, Michael Filatov, Cheol Ho Choi

2021The Journal of Physical Chemistry Letters67 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Non-radiative relaxation of the photoexcited thymine in the gas phase shows an unusually long excited-state lifetime, and, over the years, a number of models, i.e., S 1 -trapping, S 2 -trapping, and S 1 &S 2 -trapping, have been put forward to explain its mechanism. Here, we investigate this mechanism using non-adiabatic molecular dynamics (NAMD) simulations in connection with the recently developed mixed-reference spin-flip time-dependent density functional theory (MRSF-TDDFT) method. We show that the previously predicted S 2 -trapping model was due to an artifact caused by an insufficient account of the dynamic electron correlation. The current work supports the S 1 -trapping mechanism with two lifetimes, τ 1 = 30 ± 1 fs and τ 2 = 6.1 ± 0.035 ps, quantitatively consistent with the recent time-resolved experiments. Upon excitation to the S 2 (ππ*) state, thymine undergoes an ultrafast (ca. 30 fs) S 2 →S 1 internal conversion and resides around the minimum on the S 1 (n O π*) surface, slowly decaying to the ground state (ca. 6.1 ps). While the S 2 →S 1 internal conversion is mediated by fast bond length alternation distortion, the subsequent S 1 →S 0 occurs through several conical intersections, involving a slow puckering motion.

Topics & Concepts

Excited stateTime-dependent density functional theoryTrappingThymineAtomic physicsDensity functional theoryExcitationMolecular physicsChemistryRelaxation (psychology)Adiabatic processPhysicsComputational chemistryBiologyQuantum mechanicsPsychologyEcologyDNASocial psychologyBiochemistryThermodynamicsSpectroscopy and Quantum Chemical StudiesPhotochemistry and Electron Transfer StudiesPhotoreceptor and optogenetics research