Precision Spectroscopy of the Fine Structure in the a\;3u+(v=0) and c\;3g+(v=4) States of the Helium Dimer

Abstract

With four electrons, He2 is one of very few molecules for which first-principles quantum-chemical calculations that include the treatment of nonadiabatic, relativistic and quantum-electrodynamics corrections are possible. Precise spectroscopic measurements are needed as references to test these calculations. We report here on a spectroscopic measurement of the c 3g+← a 3u+ electronic transition of 4He2 at a precision ( /) of 2.5× 10-10 and with full resolution of the rotational, spin-spin and spin-rotational fine structures. The investigation focuses on transitions to the rotational levels of the c 3g+(v=4) state, located energetically above the He(1 1S0) + He(2 3S1) dissociation limit and decaying by tunneling predissociation through a barrier in the c state. The new data include a full map of the energy levels of the a 3u+(v=0) and c 3g+(v=4) states with rotational quantum numbers N up to 9 and 10, respectively, and full sets of fine-structure intervals in these levels for comparison with first-principles calculations from a parallel investigation [B. R\'acsai, P. Jeszenszki, A. Marg\'ocsy and E. Maty\'us, arXiv:2506.23879v1 (2025)]. The new data were combined with data from earlier measurements of the spectrum of the c-a band system of 4He2 to derive full sets of molecular constants for the a 3u+(v=0) and c 3g+(v=4) states with much improved precision over previous experimental results. A pronounced broadening of the linewidths of the transitions to the c 3g+(v=4,N=10) fine-structure levels is attributed to tunneling predissociation through a barrier in the potential of the c state and is quantitatively accounted for by calculations of the predissociation widths.