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Chemical precursor-dependent dual effect of doping on the gas-sensing performance of metal oxide semiconducting materials.

Authors :
Ajjaq, Ahmad
Bulut, Fatih
Ozturk, Ozgur
Acar, Selim
Source :
Sensors & Actuators B: Chemical. Dec2024, Vol. 420, pN.PAG-N.PAG. 1p.
Publication Year :
2024

Abstract

In this study, we report a chemical precursor-dependent dual effect of doping on the gas-sensing performance of metal oxide semiconducting materials. Our findings challenge the conventional notion that optimal doping consistently enhances gas-sensing properties. Acetate and nitrate salts were used as chemical precursors, lanthanum (La) was used as a dopant, and ZnO was used as a semiconducting material. All materials were synthesized under identical conditions by a two-step process involving dip coating and hydrothermal methods. Gas-sensing results demonstrated an improvement in the performance of the acetate-based doped film and a decline in that of the nitrate-based doped film compared to their respective pure counterparts. Among the produced sensors, 1 wt% La-doped ZnO sensor produced by the acetate precursor proved to be convenient for usages in real markets. It showed superior performance with a high response (62) at a relatively low operating temperature (150℃) towards 50 ppm of NH 3 gas. The sensor also demonstrated exceptional baseline stability, high short-term and long-term consistency, good selectivity, and strong tolerance to humidity (up to 70 RH%) with slightly slow adsorption-desorption rates. The dual effect was discussed with respect to dopant- and precursor-induced variations in structural and surficial characteristics, revealed by XRD, Raman, FESEM, AFM, and XPS. The discussion delved deeper into the role of chemical precursors on nanostructure growth and, for the first time, illuminated a temperature-dependent complex gas-sensing principle governed by the detected p-n shift of the semiconductor type of the sensing elements, confirmed by Hall effect. • Pure and La-doped ZnO films were hydrothermally produced by different precursors. • The dual effect of doping on gas-sensing properties of materials was discussed. • A semiconductor-type shift was observed, verified and explained. • The sensing performance was assessed via various structural and electrical parameters. • Temperature-dependent complex sensing process was elaborated based on p-n shift. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
09254005
Volume :
420
Database :
Academic Search Index
Journal :
Sensors & Actuators B: Chemical
Publication Type :
Academic Journal
Accession number :
179419681
Full Text :
https://doi.org/10.1016/j.snb.2024.136501