Abstract
Conventional gas sensing materials (e.g., metal oxides) suffer from deficient sensitivity and serve cross-sensitivity issues due to the lack of efficient adsorption sites. Herein, the heteroatom atomically doping strategy is demonstrated to significantly enhance the sensing performance of metal oxides-based gas sensing materials. Specifically, the Sn atoms were incorporated into porous Fe(2)O(3) in the form of atomically dispersed sites. As revealed by X-ray absorption spectroscopy and atomic-resolution scanning transmission electron microscopy, these Sn atoms successfully occupy the Fe sites in the Fe(2)O(3) lattice, forming the unique Sn-O-Fe sites. Compared to Fe-O-Fe sites (from bare Fe(2)O(3)) and Sn-O-Sn sites (from SnO(2)/Fe(2)O(3) with high Sn loading), the Sn-O-Fe sites on porous Fe(2)O(3) exhibit a superior sensitivity (R(g)/R(a) = 2646.6) to 1 ppm NO(2), along with dramatically increased selectivity and ultra-low limits of detection (10 ppb). Further theoretical calculations suggest that the strong adsorption of NO(2) on Sn-O-Fe sites (N atom on Sn site, O atom on Fe site) contributes a more efficient gas response, compared to NO(2) on Fe-O-Fe sites and other gases on Sn-O-Fe sites. Moreover, the incorporated Sn atoms reduce the bandgap of Fe(2)O(3), not only facilitating the electron release but also increasing the NO(2) adsorption at a low working temperature (150 °C). This work introduces an effective strategy to construct effective adsorption sites that show a unique response to specific gas molecules, potentially promoting the rational design of atomically modified gas sensing materials with high sensitivity and high selectivity.