Manjunath, G.Pothukanuri, P.Mandal, S.2026-02-052021Journal of Materials Science: Materials in Electronics, 2021, 32, 5, pp. 5713-57289574522https://doi.org/10.1007/s10854-021-05292-zhttps://idr.nitk.ac.in/handle/123456789/23315It is beneficial to develop the cost-effective, ultra-sensitive ZnO-based sensor for the rapid detection and quantification of the ammonia and formaldehyde breath markers under ambient conditions. Here, one-step solution route was adopted to formulate the aqueous combustible molecular precursor-based clogging free screen-printing ink consisting of zinc nitrate as an oxidizer, glycine as fuel, and eco-friendly binder sodium carboxymethylcellulose. The formulated precursor was deposited on the glass substrates via a screen-printing technique followed by annealing at different temperatures for an hour. Screen printed ZnO sensors processed at 500 °C with high crystallinity, less lattice distortion, low optical bandgap, and high concentration of donor defects showed remarkably high NH<inf>3</inf> gas response ~ 336 and a moderate HCHO response ~ 16.4 towards the 5 ppm and 10 ppm of the respective gases. In addition it's LOD values is drawn as 0.6 ppm and 2.9 ppm for NH<inf>3</inf> and HCHO gases, respectively, and exhibits superior selectivity towards ammonia. Faster diffusion of oxygen vacancies (V<inf>o</inf>) in the smaller crystallites resulted expeditious sensor kinetics in the screen-printed sensor processed at 400 °C. Response and recovery time were recorded to be 50 s and 50 s to the 5 ppm of NH<inf>3</inf>, respectively. The crystallinity-dominant domain overcomes the adverse effect of larger grains on the gas response of screen-printed ZnO sensor processed at 500 °C. Robust, scalable, and cost-effective screen-printed ZnO conductometric sensors demonstrated here has a potential application in clinical diagnosis, and also in monitoring the NH<inf>3</inf> and HCHO gases at low ppm-level. © 2021, The Author(s), under exclusive licence to Springer Science+Business Media, LLC part of Springer Nature.Amino acidsCost effectivenessCrystallinityCrystallitesDiagnosisFormaldehydeGasesII-VI semiconductorsOptical latticesOxide mineralsScreen printingSubstratesZinc oxideAmbient conditionsConductometric sensorDiffusion of oxygensLattice distortionsMolecular precursorResponse and recovery timeScreen printing techniqueSodium carboxymethylcelluloseAmmonia