Coulomb explosion of nanoclusters that glide along organic surfaces

A model of the Coulomb multiple dissociation (Coulomb explosion) of a nanocluster that glides at an atomic distance along an organic film at a velocity that is lower than the Bohr velocity is proposed. Nanoclusters that consist of identical atoms and films, whose molecules contain substructures of periodic diatomic valence bonds, (for example, С$_n$Н$_2n$) that have a significant dipole moment are considered. These structures can serve as antennas for IR radiation. It is shown that the dissociation process of a gliding nanocluster is induced by a picosecond pulse of highly intense photons (1014–1016 W/cm$^2$) that are radiated by IR antennas of the film as a result of the relaxation of collective vibrating excitations that are accumulated in the antenna (excimoles). These excimoles resonantly exit from the IR antennas of the film as a result of the action of the periodic Coulomb field, which appears during the gliding of a nanocluster with respect to the film molecules at a rate below the Bohr velocity. In the framework of the proposed model, the experimental results on the decay of $C_{60}^+$ ions as they glide along an organic film that contains molecules with IR antennas are analyzed.