Precision measurement of quasi-bound resonances in H$_2$ and the H + H scattering length

TL;DR

This study precisely measures and identifies quasi-bound resonances in molecular hydrogen, comparing experimental data with advanced ab initio calculations to enhance understanding of H$_2$ scattering properties.

Contribution

It provides detailed experimental identification and characterization of high-energy quasi-bound resonances in H$_2$, extending theoretical models above the dissociation limit.

Findings

Identification of four long-lived resonances above dissociation energy

Excellent agreement between measured energies and extended ab initio calculations

Verification of rotational quantum numbers through multi-step laser excitation

Abstract

Quasi-bound resonances of H$_2$ are produced via two-photon photolysis of H$_2$S molecules as reactive intermediates or transition states, and detected before decay of the parent molecule into three separate atoms. As was previously reported [K.F. Lai et al., Phys. Rev. Lett. 127, 183001 (2021)] four centrifugally bound quantum resonances with lifetimes of multiple $\mu$s, lying energetically above the dissociation limit of the electronic ground state X$^1\Sigma_g^+$ of H$_2$, were observed as X($v,J$) = (7,21)$^*$, (8,19)$^*$, (9,17)$^*$, and (10,15)$^*$, while also the short-lived ($\sim 1.5$ ns) quasi-bound resonance X(11,13)$^*$ was probed. The present paper gives a detailed account on the identification of the quasi-bound or shape resonances, based on laser detection via F-X two-photon transitions, and their strongly enhanced Franck-Condon factors due to the shifting of the wave function density to large internuclear separation. In addition, the assignment of the rotational quantum number is verified by subsequent multi-step laser excitation into autoionization continuum resonances. Existing frameworks of full-fledged ab initio computations for the bound region in H$_2$, including Born-Oppenheimer, adiabatic, non-adiabatic, relativistic and quantum-electrodynamic contributions, are extended into the energetic range above the dissociation energy. These comprehensive calculations are compared to the accurate measurements of energies of quasi-bound resonances, finding excellent agreement. Etc.