Structure, Energetics, and Spectra for the Oxygen Vacancy in Rutile:
Prominence of the Ti-H_O-Ti Bond

William R. Palfey¹, George R. Rossman¹, William A. Goddard, III², 

Under reducing conditions, rutile TiO₂ develops O vacancies (V_O) coupled to Ti³⁺ centers. It is favorable for H atoms to enter this system, either forming OH groups or occupying vacancy sites (denoted H_O) that bond to two Ti next to the vacancy. OH defects are well documented by the presence of infrared modes at ~3300 cm^‑1, while H_O is relatively under investigated. We report the energies, geometries, and vibrational frequencies of hydrogen defects in rutile predicted from Quantum Mechanics calculations, focusing on the coexistence of OH and H_O. We find that H_O is more stable than OH by 1.42 eV, leading to an infrared mode at ~1200 cm^‑1. Introducing a second H forms an OH bond with an infrared mode at ~3300 cm^-1. These results suggest that assessments of the hydrogen storage in mantle phases of rutile and similar minerals based on OH bands may significantly underestimate H concentrations.