Riddles of the structure and vibrational dynamics of HO 3 resolved near the ab initio limit.

The hydridotrioxygen (HO ₃ ) radical has been investigated in many previous theoretical and experimental studies over several decades, originally because of its possible relevance to the tropospheric HO _x cycle but more recently because of its fascinating chemical bonding, geometric structure, and vibrational dynamics. We have executed new, comprehensive research on this vexing molecule via focal point analyses (FPA) to approach the ab initio limit of optimized geometric structures, relative energies, complete quartic force fields, and the entire reaction path for cis-trans isomerization. High-order coupled cluster theory was applied through the CCSDT(Q) and even CCSDTQ(P) levels, and CBS extrapolations were performed using cc-pVXZ (X = 2-6) basis sets. The cis isomer proves to be higher than trans by 0.52 kcal mol ^-1 , but this energetic ordering is achieved only after the CCSDT(Q) milestone is reached; the barrier for cis → trans isomerization is a minute 0.27 kcal mol ^-1 . The FPA central r _e (O-O) bond length of trans-HO ₃ is astonishingly long (1.670 Å), consistent with the semiexperimental r _e distance we extracted from microwave rotational constants of 10 isotopologues using FPA vibration-rotation interaction constants (α _i ). The D ₀ (HO-O ₂ ) dissociation energy converges to a mere 2.80 ± 0.25 kcal mol ^-1 . Contrary to expectation for such a weakly bound system, vibrational perturbation theory performs remarkably well with the FPA anharmonic force fields, even for the torsional fundamental near 130 cm ^-1 . Exact numerical procedures are applied to the potential energy function for the torsional reaction path to obtain energy levels, tunneling rates, and radiative lifetimes. The cis → trans isomerization occurs via tunneling with an inherent half-life of 1.4 × 10 ^-11 s and 8.6 × 10 ^-10 s for HO ₃ and DO ₃ , respectively, thus resolving the mystery of why the cis species has not been observed in previous experiments executed in dissipative environments that allow collisional cooling of the trans-HO ₃ product. In contrast, the pure ground eigenstate of the cis species in a vacuum is predicted to have a spontaneous radiative lifetime of about 1 h and 5 days for HO ₃ and DO ₃ , respectively.