Probing molecular environment through photoemission delays

Attosecond chronoscopy has revealed small but measurable delays in photoionization, characterized by the ejection of an electron on absorption of a single photon. Ionization-delay measurements in atomic targets provide a wealth of information about the timing of the photoelectric effect, resonances,...

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Bibliographic Details
Published in:Nature physics 2020-07, Vol.16 (7), p.778-783
Main Authors: Biswas, Shubhadeep, Förg, Benjamin, Ortmann, Lisa, Schötz, Johannes, Schweinberger, Wolfgang, Zimmermann, Tomáš, Pi, Liangwen, Baykusheva, Denitsa, Masood, Hafiz A., Liontos, Ioannis, Kamal, Amgad M., Kling, Nora G., Alharbi, Abdullah F., Alharbi, Meshaal, Azzeer, Abdallah M., Hartmann, Gregor, Wörner, Hans J., Landsman, Alexandra S., Kling, Matthias F.
Format: Article
Language:English
Subjects:
119/118
140/125
639/766/36/1121
639/766/36/2796
Atomic
Chemical reactions
Classical and Continuum Physics
Complex Systems
Condensed Matter Physics
Delay
Dipoles
Electrons
Functional groups
Iodides
Iodine
Ionization
Mathematical and Computational Physics
Molecular
Optical and Plasma Physics
Photoelectric effect
Photoelectric emission
Photoelectricity
Photoionization
Physics
Physics and Astronomy
Resonance
Theoretical
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Summary:Attosecond chronoscopy has revealed small but measurable delays in photoionization, characterized by the ejection of an electron on absorption of a single photon. Ionization-delay measurements in atomic targets provide a wealth of information about the timing of the photoelectric effect, resonances, electron correlations and transport. However, extending this approach to molecules presents challenges, such as identifying the correct ionization channels and the effect of the anisotropic molecular landscape on the measured delays. Here, we measure ionization delays from ethyl iodide around a giant dipole resonance. By using the theoretical value for the iodine atom as a reference, we disentangle the contribution from the functional ethyl group, which is responsible for the characteristic chemical reactivity of a molecule. We find a substantial additional delay caused by the presence of a functional group, which encodes the effect of the molecular potential on the departing electron. Such information is inaccessible to the conventional approach of measuring photoionization cross-sections. The results establish ionization-delay measurements as a valuable tool in investigating the electronic properties of molecules. Ionization delays from ethyl iodide around a giant dipole resonance are measured by attosecond streaking spectroscopy. Using theoretical knowledge of the iodine atom as a reference, the contribution of the functional ethyl group can be obtained.
ISSN:1745-2473
1745-2481
DOI:10.1038/s41567-020-0887-8