Free-radical gases on two-dimensional transition-metal disulfides (XS(2), X = Mo/W): robust half-metallicity for efficient nitrogen oxide sensors

The detection of single gas molecules is a highly challenging work because it requires sensors with an ultra-high level of sensitivity. By using density functional theory, here we demonstrate that the adsorption of a paramagnetic unpaired free radical gas (NO) on a monolayer of XS(2) (X = Mo, W) can trigger the transition from semiconductor to half metal. More precisely, the single-layer XS(2) (X = Mo, W) with NO adsorbed on it would behave like a metal in one spin channel while acting as a semiconductor in the other spin orientation. The half-metallicity is robust and independent of the NO concentration. In contrast, no half-metallic feature can be observed after the adsorption of other free radical gases such as NO(2). The unique change in electronic properties after the adsorption of NO on transition-metal sulfides highlights an effective strategy to distinguish NO from other gas species by experimentally measuring spin-resolved transmission. Our results also suggest XS(2) (X = Mo, W) nanosheets can act as promising nanoscale NO sensors.