Development of indium doped ZnO thin films for highly sensitive acetylene (C2H2) gas sensing

The proposed article presents optimized Indium doped ZnO thin film for acetylene gas sensor. Thin films of ZnO and Indium doped ZnO of thickness 100 nm were successfully deposited on glass substrate using resistive thermal evaporation method. Structural properties have been performed by using XRD wh...

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Published inSuperlattices and microstructures Vol. 145; p. 106638
Main Authors Dev, Satya, Kumar, Pardeep, Rani, Asha, Agarwal, Ajay, Dhar, Rakesh
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.09.2020
Subjects
Acetylene gas
Homogeneous etc
IZO
MOS
MOS
Acetylene gas
IZO
Homogeneous etc
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Abstract The proposed article presents optimized Indium doped ZnO thin film for acetylene gas sensor. Thin films of ZnO and Indium doped ZnO of thickness 100 nm were successfully deposited on glass substrate using resistive thermal evaporation method. Structural properties have been performed by using XRD which reveals polycrystalline nature of the thin films. Morphological studies have been performed by using FESEM which reveals the information that thin film is homogeneous and uniform. AFM showed that with the increasing of indium doping concentration in ZnO resulting increment in vertical roughness of thin films. Further sample were tested for acetylene gas sensing using Keithley source meter and multimeter. The fabricated sensor (IZO-3) showed high sensitivity magnitude of 29.06 (100 ppm), short response and recovery time of 49.28 s and 58.45 s respectively at 150 °C operating temperature. IZO-3 sensor showed good linearity with good selectivity and excellent reproducibility. •The IZO thin films for acetylene gas sensor.•Thin films were deposited by the thermal vacuum deposition unit on the glass substrate.•The variation in resistance was recorded using Keithley source meter and multimeter connected with computer.
AbstractList The proposed article presents optimized Indium doped ZnO thin film for acetylene gas sensor. Thin films of ZnO and Indium doped ZnO of thickness 100 nm were successfully deposited on glass substrate using resistive thermal evaporation method. Structural properties have been performed by using XRD which reveals polycrystalline nature of the thin films. Morphological studies have been performed by using FESEM which reveals the information that thin film is homogeneous and uniform. AFM showed that with the increasing of indium doping concentration in ZnO resulting increment in vertical roughness of thin films. Further sample were tested for acetylene gas sensing using Keithley source meter and multimeter. The fabricated sensor (IZO-3) showed high sensitivity magnitude of 29.06 (100 ppm), short response and recovery time of 49.28 s and 58.45 s respectively at 150 °C operating temperature. IZO-3 sensor showed good linearity with good selectivity and excellent reproducibility. •The IZO thin films for acetylene gas sensor.•Thin films were deposited by the thermal vacuum deposition unit on the glass substrate.•The variation in resistance was recorded using Keithley source meter and multimeter connected with computer.
ArticleNumber 106638
Author Dhar, Rakesh
Rani, Asha
Agarwal, Ajay
Dev, Satya
Kumar, Pardeep
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Acetylene gas
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Homogeneous etc
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Snippet The proposed article presents optimized Indium doped ZnO thin film for acetylene gas sensor. Thin films of ZnO and Indium doped ZnO of thickness 100 nm were...
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StartPage 106638
SubjectTerms Acetylene gas
Homogeneous etc
IZO
MOS
Title Development of indium doped ZnO thin films for highly sensitive acetylene (C2H2) gas sensing
URI https://dx.doi.org/10.1016/j.spmi.2020.106638
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