Pawar, N.Nath, V.G.Rodney, J.D.Joshi, S.Subramanian, A.Udayashankar, N.K.2026-02-042024ACS Applied Nano Materials, 2024, 7, 17, pp. 20877-20888https://doi.org/10.1021/acsanm.4c03864https://idr.nitk.ac.in/handle/123456789/20925In this study, we explore the synthesis and gas-sensing capabilities of zinc stannate (Zn<inf>2</inf>SnO<inf>4</inf>) in three morphologies─spherical nanoparticles, urchins, and octahedrons─aiming to investigate the influence of morphology on sensing properties. The fabricated devices exhibit a significant resistance decrease upon exposure to NO<inf>2</inf> at room temperature (24 °C), indicating p-type sensing behavior. Among these morphologies, the spherical nanoparticle-based sensor exhibits the highest sensor response of 57% to 6 ppm of NO<inf>2</inf>, outperforming urchins and octahedrons by approximately 1.2 and 4.1 times, respectively. This superior performance, with response and recovery times of 6.3 s and 224 s, is attributed to enhanced redox reactions from a larger surface area and a higher proportion of oxygen interstitials. The spherical nanoparticle-based sensor also demonstrates exceptional selectivity for NO<inf>2</inf> over SO<inf>2</inf>, CO, NH<inf>3</inf>, and CH<inf>4</inf>, with a detection limit of 200 ppb. Furthermore, the sensor exhibits excellent reversibility with only 2% variation across 20 consecutive test cycles and demonstrates remarkable long-term stability, with a performance fluctuation of approximately 2.3% over 63 days without significant degradation. © 2024 American Chemical Society.Chemical sensorsMetal nanoparticlesNanosensorsZincZinc SelenideAmbientsGas sensingMetal-oxideNO 2P-typePerformancePpb levelsSelective detectionSpherical nanoparticlesZinc stannateRedox reactions