2 for the price of 1: how double ionization becomes an efficient process

Double ionization is a unique mechanism where two electrons are simultaneously emitted from an atom or molecule. Typically, it’s a very weak process occurring only a few percent of the time compared to single ionization where only one electron is emitted. This is due to double ionization requiring the correlated action of two electrons hit by an energetic photon or particle. However, in a recent experiment, is has been shown that double ionization doesn’t necessarily need to be a minor effect and can even be the primary ionization mechanism. 


The enhancement is likely due to double ionization proceeding through a new type of energy transfer process termed double intermolecular Coulombic decay, or dICD, for short. To experimentally observe this mechanism, dimers consisting of two alkali metal atoms were attached to the surface of helium nanodroplets. The dICD process, schematically shown in Fig. 1, occurs through an electronically excited helium atom (red), produced by synchrotron radiation, interacting with the neighboring alkali dimer (blue and white) resulting in energy transfer and double ionization. To distinguish dICD from other processes, the kinetic energies of the emitted electrons were measured in coincidence with their alkali ion counterparts. Shown in Fig. 2 are the resulting kinetic energy distributions for different alkali dimers where the dICD electrons are observed at lower kinetic energies than the electron from single ionization, labeled ICD. Although an alkali dimer attached to a He nanodroplet is a model case, dICD is potentially relevant for any system where it is energetically allowed.

dICD belongs to a special class of decay mechanisms where energy is exchanged between neighboring atoms or molecules leading to enhanced ionization rates. Seemingly ubiquitous in weakly-bound, condensed phase systems such as van der Waals clusters or hydrogen-bonded networks like water, these processes can contribute to radiation damage of biological systems by producing particularly harmful low-energy electrons. dICD could strongly enhance such effects through the production of two electrons for each decay.  
The experiments were performed by an international group of researchers at the GasPhase beamline at Elettra. The work was financially supported by the Carl-Zeiss-Stiftung and the Deutsche Forschungsgemeinschaft (project MU 2347/10-1).

Figure 1.  Schematic of dICD

Figure 2.  Electron kinetic energy distributions from alkali dimers

 


This research was conducted by the following research team:

A. C. LaForge1,2, M. Shcherbinin3, F. Stienkemeier1, R. Richter4, R. Moshammer5, T. Pfeifer5, and M. Mudrich3
 

Physikalisches Institut, Universität Freiburg, Freiburg, Germany. 
Department of Physics, University of Connecticut, Storrs, CT, USA. 
Department of Physics and Astronomy, Aarhus University, Aarhus C, Denmark. 
Elettra-Sincrotrone Trieste, Basovizza, Italy
Max-Planck-Institut für Kernphysik, Heidelberg, Germany



Contact persons:

Aaron LaForge, e-mail: aaron.laforge@uconn.edu


Reference

A. C. LaForge, M. Shcherbinin, F. Stienkemeier, R. Richter, R. Moshammer, T. Pfeifer & M. Mudrich, “Highly efficient double ionization of mixed alkali dimers by intermolecular Coulombic decay”, Nature Physics (2019) DOI:10.1038/s41567-018-0376-5

 
Last Updated on Monday, 11 February 2019 10:14