Critical Role of Disorder for Superconductivity in the Series of Epitaxial Ti(O,N) Films

Experimental manipulation of superconductivity is of paramount importance, not only for practical applications but also for identifying the key factors involved in electron pairing. In this work, we have undertaken a meticulous study of the superconductivity in a series of titanium compounds with a rocksalt structure, synthesized as epitaxial films. We find that substituting nitrogen (N) for oxygen (O) in titanium monoxide (TiO) with the stoichiometry close to TiO$_{0.6}$N$_{0.4}$ leads to superconductivity with a transition temperature (T$_c$) of ~2.6 K, about five times higher than that of TiO at ~0.5 K and half as high as the T$_c$ of ~6 K in titanium nitride (TiN). However, Eliashberg theoretical calculations predict similar Tc in TiO, Ti oxynitride and TiN. The analysis of electron mean free path suggests the presence of significant disorder in TiO and a remarkable reduction in the impact of disorder in oxynitrides. Density functional theory (DFT) calculations reveal that disorder decreases the coherence of electronic states for non-zero momenta, which would degrade the influence of electron-phonon. Our findings demonstrate the disorder and superconductivity depend strongly on the N/O ratio, highlighting the critical role of disorder for superconductivity in this series of Ti(O,N) materials.