Experimental characterization of singlet scattering channels in long-range Rydberg molecules

TL;DR

This study experimentally characterizes long-range Cs$_2$ Rydberg molecules, revealing two types of bound states due to triplet and mixed singlet-triplet s-wave scattering, and determines an effective singlet scattering length.

Contribution

It provides the first experimental evidence of singlet scattering channels in long-range Rydberg molecules and quantifies their role in molecular formation.

Findings

Observation of two types of molecular states: triplet and mixed singlet-triplet.

Binding energies decrease from 400 MHz to 80 MHz as n increases.

Determination of an effective singlet s-wave scattering length.

Abstract

We observe the formation of long-range Cs$_2$ Rydberg molecules consisting of a Rydberg and a ground-state atom by photoassociation spectroscopy in an ultracold Cs gas near 6s$_{1/2}$($F$=3,4)$\rightarrow$np$_{3/2}$ resonances (n=26-34). The spectra reveal two types of molecular states recently predicted by D. A. Anderson, S. A. Miller, and G. Raithel [Phys. Rev. A 90, 062518 (2014)]: states bound purely by triplet s-wave scattering with binding energies ranging from 400 MHz at n=26 to 80 MHz at n=34, and states bound by mixed singlet-triplet s-wave scattering with smaller and F-dependent binding energies. The experimental observations are accounted for by an effective Hamiltonian including s-wave scattering pseudopotentials, the hyperfine interaction of the ground-state atom, and the spin-orbit interaction of the Rydberg atom. The analysis enabled the characterization of the role of singlet scattering in the formation of long-range Rydberg molecules and the determination of an effective singlet s-wave scattering length for low-energy electron-Cs collisions.