@inbook{35ce72e7671240a4aac32f12a448bb1f,
title = "Electron and Ion Coincidence Momentum Imaging of Multichannel Dissociative Ionization of Ethanol in Intense Laser Fields",
abstract = "We investigate the multichannel dissociative ionization of C2H5OH in intense laser fields by the photoelectron-photoion coincidence momentum imaging and identify separately the ionization and subsequent electronic excitation in C2H5OH. From the energy correlation between a photoelectron and a fragment ion, we reveal the amount of the internal energy gained by C2H5OH+ from the laser field varies depending on the respective ionization and electronic excitation pathways. It is found that C2H5OH+ prepared in the electronic ground state associated with the moment of the photoelectron emission gains larger internal energy at the end of the laser pulse than that prepared in the electronically excited state at the moment of the photoelectron emission.",
author = "Ryuji Itakura and Kouichi Hosaka and Atsushi Yokoyama and Tomoya Ikuta and Fumihiko Kannari and Kaoru Yamanouchi",
note = "Funding Information: Our study described in this chapter was supported in part by the JAEA special research project “Reaction control in intense laser fields”, by MEXT/JSPS KAKENHI (Grant numbers 14077205, 17750004, 19685003, and 23350013) and by the Matsuo Foundation.",
year = "2015",
doi = "10.1007/978-3-319-06731-5_2",
language = "English",
isbn = "9783319067308",
series = "Springer Series in Chemical Physics",
publisher = "Springer New York LLC",
pages = "23--42",
booktitle = "Progress in Ultrafast Intense Laser Science",
}