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Excited State Dynamics of Cold Protonated Cytosine Tautomers: Characterization of Charge Transfer, Intersystem Crossing, and Internal Conversion Processes.

Michel BroquierSatchin SoorkiaGustavo PinoClaude Dedonder-LardeuxChristophe JouvetGilles Grégoire
Published in: The journal of physical chemistry. A (2017)
Charge transfer reactions are ubiquitous in chemical reactivity and often viewed as ultrafast processes. For DNA, femtochemistry has undeniably revealed the primary stage of the deactivation dynamics of the locally excited state following electronic excitation. We here demonstrate that the full time scale excited state dynamics can be followed up to milliseconds through an original pump-probe photodissociation scheme applied to cryogenic ion spectroscopy. Protonated cytosine is chosen as a benchmark system in which the locally excited 1ππ* state decays in the femtosecond range toward long-lived charge transfer and triplet states with lifetimes ranging from microseconds to milliseconds, respectively. A three-step mechanism (1ππ* → 1CT → 3ππ*) is proposed where internal conversion from each state can occur leading ultimately to fragmentation in the ground electronic state.
Keyphrases
  • energy transfer
  • single molecule
  • computed tomography
  • high resolution
  • single cell
  • magnetic resonance
  • circulating tumor
  • quantum dots
  • living cells
  • contrast enhanced
  • dual energy
  • mass spectrometry
  • electron transfer