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Projekt Druckansicht

Die Photodynamik des Ar-I2-Komplexes und die Bildung von chemisch gebundenem Argon

Fachliche Zuordnung Physikalische Chemie von Molekülen, Flüssigkeiten und Grenzflächen, Biophysikalische Chemie
Förderung Förderung von 2014 bis 2017
Projektkennung Deutsche Forschungsgemeinschaft (DFG) - Projektnummer 258395149
 
Erstellungsjahr 2018

Zusammenfassung der Projektergebnisse

Dissociation of superexcited states of I2 in He nanodroplets produces both cationic and anionic fragments similar to the free I2 molecule in the gas phase; the charged fragments are ejected out of the droplets either as pristine ions or as complexes with attached He atoms. The velocity of ejected product ions is massively reduced with respect to the gasphase. A sharp drop in the velocity with increasing number of He atoms attached to the ion is observed, similar to previous findings for neutral fragments. The speeds of anionic products are about half as high as those of the cations of the same mass. The cationic velocity distributions are strongly anisotropic despite the reduction of the absolute speeds by interaction with the He nanodroplet. This shows that the information about the direction of ejection of the fragment cation is largely retained. However, the observed positive anisotropy contrasts the negative anisotropy measured in the gasphase, implying that a different dissociation mechanism is at the origin of the detected ions. The pump-probe dynamics measured for the most prominent I+ and I- product ions shows now resemblance with the gasphase dynamics, but a strong dependence on the He droplet size. This indicates that the observed dynamics is entirely dominated by the interaction of the excited I2 and the I+ and I-ions with the He nanodroplet, similar to our previous observations for excited atoms attached to He nanodroplets. In future experiments using a pulsed nozzle suitable for corrosive gases, we will resume the originally proposed studies of the ArI2 complex. Furthermore, the detection of I+ and I- in coincidence, generated by laser-induced photoionization or by photoionization using vacuum ultraviolet radiation from a synchrotron, will reveal further details about the complex photodynamics of superexcited states of iodine and its complexes.

Projektbezogene Publikationen (Auswahl)

 
 

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