Laser-induced Coulomb explosion of heteronuclear alkali dimers on helium nanodroplets

Abstract

A sample mixture of alkali homonuclear dimers, Ak2 and Ak2 and heteronuclear dimers, AkAk, residing on the surface of helium nanodroplets are Coulomb exploded into pairs of atomic alkali cations, (Ak+,Ak+), (Ak +,Ak +), (Ak+, Ak +), following double ionization induced by an intense 50 fs laser pulse. The measured kinetic energy distribution P(Ekin) of both the Ak+ and the Ak + fragment ions contains overlapping peaks due to contributions from Coulomb explosion of the homonuclear and the heteronuclear dimers. Using a coincident filtering method based on the momentum division between the two fragment ions in each Coulomb explosion event, we demonstrate that the individual P(Ekin) pertaining to the ions from either the heteronuclear or from the homonuclear dimers can be retrieved, for both the Ak+ and for the Ak + fragment ions. This filtering method works through the concurrent detection of two-dimensional velocity images of the Ak+ and the Ak + ions implemented through the combination of a velocity map imaging spectrometer and a TPX3CAM detector. The key finding is that P(Ekin) for heteronuclear alkali dimers can be distinguished despite the simultaneous presence of homonuclear dimers. From P(Ekin) we determine the distribution of internuclear distances P(R) via the Coulomb explosion imaging principle. We report results for LiK and for NaK but our method should should also work for other heteronuclear dimers and for differentiating between different isotopologues of homonuclear dimers.