Laser-induced Coulomb explosion of the LiI molecule and of its dimer

Abstract

A gas-phase sample consisting of lithium iodide, LiI, molecules and their dimer (LiI)2, are Coulomb exploded by an intense 25 femtosecond laser pulse. In the case of LiI, we focus on the double ionization that creates a pair of Li+ and I+ recoil ions. From the kinetic energy distribution of the Li+ ions, extracted using coincidence filtering, we determine the distribution of internuclear distances P(R) via the ground state potential curve of LiI2+ obtained from an ab initio calculation that accounts for non-Coulombic effects. We find that the center of P(R) is close to the expected internuclear separation based on the three vibrational states of LiI populated, whereas the width of P(R) exceeds the theoretical value by 52 %. We discuss if fragmentation via excited LiI2+ potential curves affects the determination of P(R). In the case of the dimer, (LiI)2, we observe kinetic energies and relative emission directions of Li+, I+, and I2+ recoil ions consistent with Coulomb explosion of the parallelogram-shaped dimer after removing up to six electrons by the laser pulse.