English

Inelastic electron scattering induced quantum coherence: isotope effect

Chemical Physics 2026-07-01 v1

Abstract

Recent discoveries of electron-induced coherence in both resonant and non-resonant interactions have introduced new perspectives in the field. In non-resonant processes, coherence has been observed in dipolar dissociation, where electron-induced excitation forms a coherent superposition of states of opposite parities, resulting in asymmetry in the angle-differential cross-section of the process relative to the incident electron beam. Notably, an isotope effect has been observed in D2D_2 at 50 eV, where heavier isotopes exhibit diminished asymmetry due to their longer dissociation times. Here, we report the isotope effect on quantum coherence in D2D_2 across different electron energies. Additionally, we investigate the role of coherence in the isotopologue HD. Our findings reveal that the asymmetric masses in HD do not influence electron-impact excitation, leading to similar asymmetry in the angular distributions of HH^- and DD^- ions. This observation is explained by the homonuclear-like behavior of HD within the Franck-Condon region.

Cite

@article{arxiv.2607.00806,
  title  = {Inelastic electron scattering induced quantum coherence: isotope effect},
  author = {Akshay Kumar and Vaibhav S. Prabhudesai},
  journal= {arXiv preprint arXiv:2607.00806},
  year   = {2026}
}