Ultra-sensitive H2S sensor based on sunflower-like In-doped ZnO with enriched oxygen vacancies

Abstract

Metal oxide sensors face the challenge of high response and fast recovery at low operating temperatures for the detection of toxic and flammable hydrogen sulfide (H₂S) gases. Herein, novel In-doped ZnO with a sunflower-like structure and tunable surface properties was rationally synthesized. The substitutional In atom in the ZnO crystal can dramatically enhance the concentration of oxygen vacancies (O_v), the In–ZnO sites are responsible for fast recovery, and the formation of sub-stable sulfide intermediates gives rise to the high response towards H₂S. As a result, the response of the optimized 4In–ZnO sensor is 3538.36 to 50 ppm H₂S at a low operating temperature of 110 °C, which is 106 times higher than that of pristine ZnO. Moreover, the response time and recovery time to 50 ppm H₂S are 100 s and 27 s, respectively, with high selectivity and stability. First-principles calculations revealed that 4In–ZnO with rich O_v exhibited higher adsorption energy for the H₂S molecule than pristine ZnO, resulting in effortless H₂S detection. Our work lays the foundation for the rational design of highly sensitive gas sensors through precise doping of atoms in oxygen-rich vacancies in semiconductor materials.