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Abstrakty
In this work, nickel oxide was deposited on a glass substrate at by spray deposition technique; the structural, optical and electrical properties were studied at different NiO concentrations (0.05, 0.10 and 0.15 mol.l-1). Polycrystalline NiO films with a cubic structure with a strong (111) preferred orientation were observed at all sprayed films with minimum crystallite size of 11.97 nm was attained of deposited film at 0.1 mol.l-1. However, α-Ni(OH)2 was observed at 0.15 mol.l-1. The NiO thin films have good transparency in the visible region, the band gap energy varies from 3.54 to 376 eV was affected by NiO concentration, it is shown that the NiO thin film prepared at 0.05 mol.l-1 has less disorder with few defects. The NiO film deposited at 0.15 mol.l-1 has the electrical conductivity was 0.169 (Ω.cm)-1.
Wydawca
Czasopismo
Rocznik
Strony
79--87
Opis fizyczny
Bibliogr. 22 poz., rys., tab.
Twórcy
autor
- Mechanical Department, Faculty of Technology, University of El-Oued, El-Oued 39000, Algeria
- VTRS Laboratory, Institute of Technology, University of El-Oued, El-Oued 39000, Algeria
autor
- Mechanical Department, Faculty of Technology, University of El-Oued, El-Oued 39000, Algeria
autor
- Material Sciences Department, University of Biskra, Biskra 07000, Algeria
autor
- Mechanical Department, Faculty of Technology, University of El-Oued, El-Oued 39000, Algeria
autor
- Mechanical Department, Faculty of Technology, University of El-Oued, El-Oued 39000, Algeria
autor
- Mechanical Department, Faculty of Technology, University of El-Oued, El-Oued 39000, Algeria
Bibliografia
- 1. Gund G.S., Lokhande C.D., Park H.S., Controlled synthesis of hierarchical nanoflake structure of NiO thin film for supercapacitor application, Journal of Alloys and Compounds 741 (2018) 549-556.
- 2. Aoun Y., Meneceur R., Benramache S., Maaoui B., Sprayed NiO-Doped p-Type Transparent ZnO Thin Films Suitable for Gas-Sensing Devices, Physics of the Solid State 62 (1) (2020) 131-136.
- 3. Raza M.H., Movlaee K., Wu Y., El‐Refaei S.M., Karg M., Leonardi S.G., Neri G., Pinna N., Tuning the NiO Thin Film Morphology on Carbon Nanotubes by Atomic Layer Deposition for Enzyme‐Free Glucose Sensing, ChemElectroChem 6 (2019) 383-392.
- 4. Herissi L., Hadjeris L., Aida M.S., Bougdira J., Properties of (NiO) 1-x (ZnO) x thin films deposited by spray pyrolysis, Thin Solid Films 605 (2016) 116-120.
- 5. Guezzoun H., Benhaoua B., Benramache S., Synthesis and characterizations of nanocrystalline Na and Al codoped NiO thin films, International Journal of Integrated Engineering 12 (1) (2020) 204-209.
- 6. Shang Z.W., Hsu H.H., Zheng Z.W., Cheng C.H., Progress and challenges in p-type oxide-based thin film transistors, Nanotechnology Reviews 8 (2019) 422-443.
- 7. Hotovy I., Spiess L., Predanocy M., Rehacek V., Racko J., Sputtered nanocrystalline NiO thin films for very low ethanol detection, Vacuum 107 (2014) 129-131.
- 8. Manouchehri I., Mehrparvar D., Moradiana R., Gholami K., Osati T., Investigation of structural and optical properties of copper doped NiO thin films deposited by RF magnetron reactive sputtering, Optik 127 (2016) 8124-8129.
- 9. Garcia-Garcia F.J., Salazar P., Yubero F., González-Elipe A.R., Non-enzymatic glucose electrochemical sensor made of porous NiO thin films prepared by reactive magnetron sputtering at oblique angles, Electrochimica Acta 201 (2016) 38-44.
- 10. Mironova-Ulmane N., Kuzmin A., Sildos I., Puust L., Grabis J., Magnon and Phonon Excitations in Nanosized NiO, Latvian Journal of Physics and Technical Sciences 56 (2019) 726-737.
- 11. Manouchehri I., Mehrparvar D., Moradian R., Gholami K., Osati T., Investigation of structural and optical properties of copper doped NiO thin films deposited by RF magnetron reactive sputtering, Optik 127 (2016) 8124-8129.
- 12. Bahramian A., Eyraud M., Vacandio F., Hornebecq V., Djenizian T., Knauth P., Single-step electrodeposition of superhydrophobic black NiO thin films, Journal of Applied Electrochemistry 49 (2018) 621-629.
- 13. Khalaf M.M., Hany M., El-Lateef Abd, Corrosion protection of mild steel by coating with TiO2 thin films co-doped with NiO and ZrO2 in acidic chloride environments, Materials Chemistry and Physics 177 (2016) 250-265.
- 14. Diha A., Benramache S., Fellah L., The Crystalline Structure, Optical and Conductivity Properties of Fluorine Doped ZnO Nanoparticles, Journal of Nano and Electronic Physics 11 (2019) 03002.
- 15. Varughese G., Rini V., Suraj S.P., Usha K.T., Characterisation and Optical Studies of Copper Oxide Nanostructures Doped with Lanthanum Ions, Advances in Materials Science 14 (2014) 59-60
- 16. Kate R.S., Bulakhe S.C., Deokate R.J., Effect of Substrate Temperature on Properties of Nickel Oxide (NiO) Thin Films by Spray Pyrolysis, Journal of Electronic Materials 48 (2019) 3220-3228.
- 17. Panneerselvam V., Chinnakutti K.K., Salammal S.T., Soman A.K., Parasuraman K., Vishwakarma V., Kanagasabai V., Role of copper/vanadium on the optoelectronic properties of reactive RF magnetron sputtered NiO thin films, Applied Nanoscience 8 (2018) 1299–1312.
- 18. Aoun Y., Marrakchi M., Benramache S., Benhaoua B., Lakel S., Cheraf A., Preparation and Characterizations of Monocrystalline Na Doped NiO Thin Films, Materials Research 21 (2018) e20170681.
- 19. Benramache S., Aoun Y., Lakel S., Mourghade H., Gacem R., Benhaoua B., Effect of Annealing Temperature on Structural, Optical and Electrical Properties of ZnO Thin Films Prepared by Sol-Gel Method, Journal of Nano- and Electronic Physics 10(6) (2018) 06032.
- 20. Mahmoud S.A., Alshomer S., Tarawnh M.A., Structural and optical dispersion characterisation of sprayed nickel oxide thin films, Journal of Modern Physics 2( 2011) 1178-1186.
- 21. Nakate U.T., Ahmad R., Patil P., Yu Y.T., Hahn Y.B., Ultra thin NiO nanosheets for high performance hydrogen as sensor device, Applied Surface Science 506 (2020) 144971.
- 22. Salunkhe P., Ali M. A.V., Kekuda D., Investigation on tailoring physical properties of Nickel Oxide thin films grown by dc magnetron sputtering, Materials Research Express 7 (2020) 016427.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-936ca6d3-29df-408c-9e5b-488efb642d9b