Bonn 2000 – wissenschaftliches Programm

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MO: Molekülphysik

MO 24: kleine Moleküle

MO 24.4: Vortrag

Freitag, 7. April 2000, 12:00–12:15, HS VI

Electron Induced Vibrational De-Excitation of H₂⁺ — •Sven Krohn¹, Zohar Amitay¹, Adam Baer¹, Lars Knoll², Michael Lange², Jacob Levin², Dirk Schwalm², Zeev Vager¹, Roland Wester², Andreas Wolf², and Daniel Zajfman¹ — ¹Weizmann Institute of Science, 76100 Rehovot — ²Max-Planck-Institut für Kernphysik, Heidelberg

Using foil-induced Coulomb explosion imaging combined with the heavy-ion storage ring technique, the relative populations of the first 6 vibrational levels in a beam of H₂⁺ ions interacting with low kinetic energy electrons have been measured for different storage times at the storage ring TSR located at the MPI für Kernphysik.

The slow electrons interact with the H₂⁺ ions through two main processes: On the one hand dissociative recombination (DR) occurs where the electron is absorbed and the molecule dissociates. Since the DR rate depends strongly on the initial vibrational level, this can selectively deplete specific vibrational levels in the ion beam. On the other hand the electron is subject to superelastic collision (SEC) processes, which also is accompanied by vibrational de-excitation.

We demonstrate that SEC caused by interactions with electrons leads to vibrational cooling of H₂⁺ during storage times of up to 15 s.

Using a rate equation model we show that the theoretically predicted rates for this process are too low by at least an order of magnitude in order to reproduce the observed time dependence of the vibrational population. This work was partly funded by BMBF (DIP project) and GIF.