Ionization Energy of Rb2 by electric field-ionization of molecular Rydberg states

Abstract

We report the measurement of the ionization energy of the 85Rb2 molecule through resonantly enhanced 2-photon ionization in a supersonic beam. The first photon excites the X1g+ (vX = 0)→ B1u (vB = 2) transition, while the second photon wavenumber is scanned over the 16720 cm-1-16750 cm-1 range, thus yielding a structured spectrum of Rb2+ ions extracted by an electric field and recorded by mass spectrometry. We modeled the onset of the ionization signal as a function of the electric field strength between 18 V/cm and 180 V/cm, leading to the Rb2 ionization energy Ei = 31497.3 0.6 cm-1, and to the dissociation energy of the Rb2+ ground state D0 = 6158.2 0.6 cm-1. Our measured value Ei is found to be 149.3 cm-1 larger than the one reported in the experiment by Bellos et al. [Phys. Rev. A 87, 012508 (2013)]. Our value of D0 agrees with our theoretical determination using a quantum chemistry approach. Using a simple theoretical model, we assign unevenly spaced structures of the ionization spectrum to molecular Rydberg levels belonging to several series that converge to the lowest vibrational levels of Rb2+.