Enhancement in the sensitivity and selectivity of Cu functionalized MoS2 nanoworm thin films for nitrogen dioxide gas sensor

•Pure MoS2 and Cu-MoS2 thin films were fabricated on the glass substrate using reactive co-sputtering.•Sputtered deposited pure and Cu-MoS2 thin films showed nanoworms morphology.•Cu-MoS2 sensor shows high sensing response (∼30 %) as compared to the pure MoS2 (13 %) sensor towards 20 ppm of NO2 gas...

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Bibliographic Details
Published in:Materials research bulletin 2022-06, Vol.150, p.111784, Article 111784
Main Authors: Tyagi, Shrestha, Kumar, Arvind, Kumar, Ashwani, Gautam, Yogendra K., Kumar, Virendra, Kumar, Yogesh, Singh, Beer Pal
Format: Article
Language:English
Subjects:
Gas sensor
MoS2 nanoworms thin films
Nitrogen dioxide
Reactive co-sputtering
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Summary:•Pure MoS2 and Cu-MoS2 thin films were fabricated on the glass substrate using reactive co-sputtering.•Sputtered deposited pure and Cu-MoS2 thin films showed nanoworms morphology.•Cu-MoS2 sensor shows high sensing response (∼30 %) as compared to the pure MoS2 (13 %) sensor towards 20 ppm of NO2 gas in dry air at 100°C.•Cu-MoS2 sensor exhibits fast response and recovery time of 54 sec and 82 sec respectively. In this work, we report the controlled synthesis of Cu functionalized MoS2 nanoworm thin films based NO2 sensors using a reactive co-sputtering technique. Structural and surface morphological properties were studied using XRD and FESEM analysis, respectively. The surface chemistry and defects study of as-prepared samples were carried out using X-ray photoelectron spectroscopy and photoluminescence spectra, respectively. In addition, further insights into the absorbance and band gap studies were gained using UV-Visible spectroscopy. The sensing performance of pure MoS2 and Cu-MoS2 thin films was studied towards nitrogen dioxide (NO2) gas concentrations (2-200 ppm) at the optimum working temperature of 100°C. The Cu-MoS2 sensor provides a high sensing response as compared to the pure MoS2 thin-film sensor towards 20 ppm of NO2 gas with a fast response and recovery time. The Cu-MoS2 thin-film sensor is highly sensitive, stable, and selective towards NO2 against NH3, CO, and H2 gases. The developed 2D MoS2 thin-film-based sensor chip, due to its remarkable performance, might be used for low (2 ppm) detection of NO2 under a low working temperature regime. [Display omitted]
ISSN:0025-5408
1873-4227
DOI:10.1016/j.materresbull.2022.111784