Surface characterization and gas sensing performance of yttrium doped TiO2 nanofilms prepared by automated nebulizer spray pyrolysis (ANSP)

Y x Ti 1−x O 2 nanofilms were deposited on glass substrate at 500 °C by automated nebulizer spray pyrolysis route. The influence of yttrium concentration on XRD shows the stabilized anatase tetragonal polycrystalline nature and * (222), * (400) plane orientation of Y 2 O 3 were revealed by Y = 10%....

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Bibliographic Details
Published in:Journal of materials science. Materials in electronics 2018, Vol.29 (1), p.392-401
Main Authors: Gopala Krishnan, V., Elango, P., Ganesan, V.
Format: Article
Language:English
Subjects:
Characterization and Evaluation of Materials
Chemistry and Materials Science
Materials Science
Optical and Electronic Materials
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Summary:Y x Ti 1−x O 2 nanofilms were deposited on glass substrate at 500 °C by automated nebulizer spray pyrolysis route. The influence of yttrium concentration on XRD shows the stabilized anatase tetragonal polycrystalline nature and * (222), * (400) plane orientation of Y 2 O 3 were revealed by Y = 10%. An XPS spectrum reveals the primary elements such as O 1s, Ti 2p, Y 3d, Ti 3p and C 1s with a binding energy respectively. The morphological study of FESEM shows the modification from granular spherical to honeycomb structure based on yttrium concentration. Optical study shows the blue shift of sharp absorption edge with increased band gap values ( E g  = 3.20 eV–3.78 eV) is depends upon Y concentration. Notably, gas sensing performance of Y x Ti 1−x O 2 shows the highest sensitivity response to Y = 10% (Y 0.10 Ti 9.90 O 2 ) of NH 3 at 150 °C with 300 ppm gas concentration and all the films exhibits better sensitivity response in order to NH 3  > C 2 H 6 O > C 3 H 6 O> CH 4 O > C 3 H 8 O.
ISSN:0957-4522
1573-482X
DOI:10.1007/s10854-017-7928-9