Nature Communications (Oct 2024)

Few-femtosecond time-resolved study of the UV-induced dissociative dynamics of iodomethane

  • Lorenzo Colaizzi,
  • Sergey Ryabchuk,
  • Erik P. Månsson,
  • Krishna Saraswathula,
  • Vincent Wanie,
  • Andrea Trabattoni,
  • Jesús González-Vázquez,
  • Fernando Martín,
  • Francesca Calegari

DOI
https://doi.org/10.1038/s41467-024-53183-8
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 8

Abstract

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Abstract Ultraviolet (UV) light that penetrates our atmosphere initiates various photochemical and photobiological processes. However, the absence of extremely short UV pulses has so far hindered our ability to fully capture the mechanisms at the very early stages of such processes. This is important because the concerted motion of electrons and nuclei in the first few femtoseconds often determines molecular reactivity. Here we investigate the dissociative dynamics of iodomethane following UV photoexcitation, utilizing mass spectrometry with a 5 fs time resolution. The short duration of the UV pump pulse (4.2 fs) allows the ultrafast dynamics to be investigated in the absence of any external field, from well before any significant vibrational displacement occurs until dissociation has taken place. The experimental results combined with semi-classical trajectory calculations provide the identification of the main dissociation channels and indirectly reveal the signature of a conical intersection in the time-dependent yield of the iodine ion. Furthermore, we demonstrate that the UV-induced breakage of the C-I bond can be prevented when the molecule is ionized by the probe pulse within 5 fs after the UV excitation, showcasing an ultrafast stabilization scheme against dissociation.