English

The Molecular Migdal Effect

High Energy Physics - Phenomenology 2022-12-28 v1 Materials Science Quantum Gases Atomic Physics Chemical Physics

Abstract

Nuclear scattering events with large momentum transfer in atomic, molecular, or solid-state systems may result in electronic excitations. In the context of atomic scattering by dark matter (DM), this is known as the Migdal effect, but the same effect has also been studied in molecules in the chemistry and neutron scattering literature. Here we present two distinct Migdal-like effects from DM scattering in molecules, which we collectively refer to as the molecular Migdal effect: a center-of-mass recoil, equivalent to the standard Migdal treatment, and a non-adiabatic coupling resulting from corrections to the Born-Oppenheimer approximation. The molecular bonds break spherical symmetry, leading to large daily modulation in the Migdal rate from anisotropies in the matrix elements. Our treatment reduces to the standard Migdal effect in atomic systems but does not rely on the impulse approximation or any semiclassical treatments of nuclear motion, and as such may be extended to models where DM scatters through a long-range force. We demonstrate all of these features in a few simple toy models of diatomic molecules, namely H2+{\rm H}_2^+, N2_2, and CO, and find total molecular Migdal rates competitive with those in semiconductors for the same target mass. We discuss how our results may be extended to more realistic targets comprised of larger molecules which could be deployed at the kilogram scale.

Keywords

Cite

@article{arxiv.2208.09002,
  title  = {The Molecular Migdal Effect},
  author = {Carlos Blanco and Ian Harris and Yonatan Kahn and Benjamin Lillard and Jesús Pérez-Ríos},
  journal= {arXiv preprint arXiv:2208.09002},
  year   = {2022}
}

Comments

v1: 15+2 pages, 7 figures

R2 v1 2026-06-25T01:48:22.575Z