Physical Review X (Jun 2016)

Ultrafast Dynamics of a Nucleobase Analogue Illuminated by a Short Intense X-ray Free Electron Laser Pulse

  • K. Nagaya,
  • K. Motomura,
  • E. Kukk,
  • H. Fukuzawa,
  • S. Wada,
  • T. Tachibana,
  • Y. Ito,
  • S. Mondal,
  • T. Sakai,
  • K. Matsunami,
  • R. Koga,
  • S. Ohmura,
  • Y. Takahashi,
  • M. Kanno,
  • A. Rudenko,
  • C. Nicolas,
  • X.-J. Liu,
  • Y. Zhang,
  • J. Chen,
  • M. Anand,
  • Y. H. Jiang,
  • D.-E. Kim,
  • K. Tono,
  • M. Yabashi,
  • H. Kono,
  • C. Miron,
  • M. Yao,
  • K. Ueda

DOI
https://doi.org/10.1103/PhysRevX.6.021035
Journal volume & issue
Vol. 6, no. 2
p. 021035

Abstract

Read online Read online

Understanding x-ray radiation damage is a crucial issue for both medical applications of x rays and x-ray free-electron-laser (XFEL) science aimed at molecular imaging. Decrypting the charge and fragmentation dynamics of nucleobases, the smallest units of a macro-biomolecule, contributes to a bottom-up understanding of the damage via cascades of phenomena following x-ray exposure. We investigate experimentally and by numerical simulations the ultrafast radiation damage induced on a nucleobase analogue (5-iodouracil) by an ultrashort (10 fs) high-intensity radiation pulse generated by XFEL at SPring-8 Angstrom Compact free electron Laser (SACLA). The present study elucidates a plausible underlying radiosensitizing mechanism of 5-iodouracil. This mechanism is independent of the exact composition of 5-iodouracil and thus relevant to other such radiosensitizers. Furthermore, we found that despite a rapid increase of the net molecular charge in the presence of iodine, and of the ultrafast release of hydrogen, the other atoms are almost frozen within the 10-fs duration of the exposure. This validates single-shot molecular imaging as a consistent approach, provided the radiation pulse used is brief enough.