In this study, copper oxide thin films prepared by the sol–gel method, have been deposed onto glass substrates by the spin coating technique. Our target was to study their properties and improve them for photovoltaic use. These properties were optimized by varying the temperature annealing and the molar concentration of the precursor solutions. The effects of the annealing temperature on the structural and optical properties of the thin films are studied. It was found that the film treated at 550°C shows a higher absorbance. Then by using this optimized temperature, CuO thin films of various molar concentrations, were deposited at the same experimental conditions. The structural analysis by X- ray diffraction (XRD) shows that all the samples are polycrystalline with monoclinic crystal structure. Raman scattering measurements of all thin films confirms the structure of CuO. The optical properties of the films were characterized by UV–Visible–NIR spectrophotometry, which shows that the films show high absorbance in the visible region. Their optical band gap decreases from 3.68 to 2.44 eV when the molar concentration of precursor solutions increases from 0.1 to 0.5 M. The electrical measurements show that the resistivity of the films varies slightly from 84 Ω cm to 124 Ω cm as the molar concentration increases.
| Published in | American Journal of Physics and Applications (Volume 6, Issue 2) |
| DOI | 10.11648/j.ajpa.20180602.13 |
| Page(s) | 43-50 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
| Copyright |
Copyright © The Author(s), 2024. Published by Science Publishing Group |
Sol–Gel, Spin-Coating, Copper Oxide, Thin Films, Physical Properties
| [1] | F. Marabelli, G. B. Parravicini, F. Salghetti-Drioli (1995) Optical gap of CuO. Physical, Review B 52: 1433-1436. |
| [2] | Wei-Tang Yao, Shu-Hong Yu, etc (2005) Formation of uniform CuO nanorods by spontaneous aggregation: selective synthesis of CuO, Cu2O, and Cu nanoparticles by a solid-liquid phase are discharge process, The Journal of Physical Chemistry B: 109: 14011-14016. |
| [3] | F. Marabelli, G. B. Parravicini (1994) Evidence of localized states in the optical gap of CuO, Physica B 199-200: 255-256. |
| [4] | Cyrus Wadia, A. Paul Alivisatos, Duniel M. Kammen (2009) Materials availability expands the opportunity for large-scale photovoltaics deployment, Environmental Science & Technology 43: 2070-2077. |
| [5] | Gavin Conibeer. (2007) Third-generation photovolatics, Materials Today 10: 42-50. |
| [6] | N. López, L. A. Reichertz, K. M. Yu, K. Campman, W. Walukiewicz (2011) Band structure for multiband solar cells, Physical Review Letters 106: 028701. |
| [7] | A. Polman, H. A. Atwater (2012) Nat. Mater. 11: 174. |
| [8] | L. Zhu, G. Shao, J. K. Luo, (2011) Semicond. Sci. Tech. 26: 085026. |
| [9] | L. A. Patil, D. R. Patil (2006) Heterocontact type CuO-modified SnO2 sensor for the detection of a ppm level H2S gas at room temperature, Sensors & Actuators B: Chemical 120: 316-323. |
| [10] | YunZhe Feng, Xiaolin Zheng (2010) Plasma-enhanced catalytic CuO nanowires for CO oxidation, Nano Letters 10: 4762-4766. |
| [11] | C. C. Chusuei, M. A. Brookshier, D. W. Goodman (1999) Correlation of relative X-ray photoelectron spectroscopy shake-up intensity with CuO particle size, Langmuir 15: 2806-2808. |
| [12] | Jiatao Zhang, Junfeng Liu, et al (2006) Nearly monodisperse Cu2O and CuO nanospheres: Preparation and Application for sensitive gas sensors, Chemistry of Materials 18: 867-871. |
| [13] | P. Raksa, S. Nilphai, A. Gardchareon, S. Choopun (2009) Copper oxide thin films and nanowire as a barrier in ZnO dye-sensitized solar cells, Thin Solid Films 517: 4741-4744. |
| [14] | Fei Gao, Xiao-Jing Liu, Jun-Shan Zhang, Mei-Zhou Song, Ning Li (2012) Photovoltaic properties of the p-CuO/n-Si heterojunction prepared through reactive magnetron sputtering, Journal of Applied Physics 111: 084507. |
| [15] | Sang-Yun Sung, Se-Yun Kim, Kwang-Min Jo, Joon-Hyung Lee, Jeong-Joo Kim, Sang-Gon Kim, Kyoung-Hoon Chai, S. J. Pearton, D. P. Norton, YoungWoo Heo (2010) Fabrication of p-channel thin-film transistors using CuO active layers deposited at low temperature, Applied Physics Letters 97: 222109. |
| [16] | C. Díaz-Guerra, M. vila, J. Piqueras (2010) Exchange bias in single-crystalline CuO nanowires, Applied Physics Letters 96: 193105. |
| [17] | A. Chen, H. Long, X. Li, Y. Li, G. Yang, P. Lu, (2009) Controlled growth and characteristics of single-phase Cu2O and CuO films by pulsed laser deposition, Vacuum 38: 927-930. |
| [18] | Hiroki Kidowaki, Takeo Oku, Tsuyoshi Akiyama, Atsushi Suzuki (2012) Fabrication and Characterization of CuO-based Solar Cells, Journal of Materials Science Research January, Vol. 1, No. 1. |
| [19] | Fei Gao, Xiao-Jing Liu, Jun-Shan Zhang, Mei-Zhou Song, and Ning Li (2012) Photovoltaic properties of the p-CuO/n-Si heterojunction prepared through reactive magnetron sputtering, Journal of applied physics 111: 084507. |
| [20] | A. Zainelabdin, S. Zaman, G. Amin, O. Nur, M. Willander (2012) Optical and current transport properties of CuO/ZnO nanocoral p–n heterostructure hydrothermally synthesized at low temperature, Appl. Phys. A: 108, 921. |
| [21] | L. Liu, K. Hong, X. Ge, M. Xu, (2014) Aligned CuO nanorod arrays: fabrication and anisotropic ferromagnetism, Appl. Phys. A: 115-1147. |
| [22] | L. Armelao, D. Barreca, M. Bertapelle, G. Bottaro, C. Sada, E. Tondello (2003) A sol–gel approach to nanophasic copper oxide thin films, Thin Solid Films: 442-4852. |
| [23] | W. Wang, Z. Liu, Y. Liu, C. Xu, C. C. Zheng, G. Wang (2003) A simple wet-chemical synthesis and characterization of CuO nanorods, Appl. Phys. A: 76-417. |
| [24] | V. F. Drobny, D. L. Pulfrey (1979) Properties of reactively-sputtered copper oxide thin films, Thin Solid Films 61: 89–98. |
| [25] | K. P. Muthe, J. C. Vyas, Savita N. Narang, D. K. Aswal, S. K. Gupta, Debarati Bhattacharya, R. Pinto, G. P. Kothiyal, S. C. Sabharwal (1998) A study of the CuO phase formation during thin film deposition by molecular beam epitaxy, Thin Solid Films 324: 37–43. |
| [26] | N. Mukherjee, B. Show, S. K. MAji, U. Madhu, S. K. Bhar, B. C. Mitra, G. G. Khan, A. Mondal (2011). CuO nano-whiskers: electrodeposition, Raman analysis, photoluminescence study and photocatalytic activity, Mater. Letters 65: 3248-3250. |
| [27] | A. A. Al-Ghamdi, Waleed E. Mahmoud, S. J. Yaghmour, F. M. Al- Marzouki (2009) Structure and optical properties of nanocrystalline NiO thin film synthesized by sol–gel spin-coating method, J. Alloys Compd 486: 9–13. |
| [28] | L. J Van der Pauw (1958) A method of measuring specific resistivity and Hall effect of discs of arbitrary shape, Philips Res Repts, 13: 1-9. |
| [29] | C. S. Garrett, T. B. Massalski (1980) Structure of Metals, Pergamon Press, Oxford. |
| [30] | Dattarya Jundale, Shailesh Pawar, Manik Chougule, Prasad Godse, Sanjay Patil Bharat Raut, Shashwati Sen, Vikas Patil (2011) Nanocrystalline CuO Thin Films for H2S Monitoring, Microstructural and Optoelectronic Characterization, Journal of Sensor Technology 1: 36-46 doi:10.4236/jst.2011.12006 Published Online June 2011. |
| [31] | B. D. Cullity, S. R. Stock, Elements of X-Ray Diffraction (2001), 3rd ed., Prentice Hall, Upper Saddle River, New Jersey. |
| [32] | Shou-Yi Kuo, Wei-Chun Chen, Chin-Pao Cheng (2006) Investigation of annealing-treatment on the optical and electrical properties of sol-gel-derived zinc oxide thin films, Superlattices and Microstructures 39: 162–170. |
| [33] | Z. Ghorannevis, M. T. Hosseinnejad, M. Habibi, P. Golmahdi (2015) Effect of substrate temperature on structural, morphological and optical properties of deposited Al/ZnO films, J Theor Appl Phys 9: 33–38 DOI 10.1007/s40094-014-0157-1. |
| [34] | Yunus Akaltun (2015) Effect of thickness on the structural and optical properties of CuO thin films grown by successive ionic layer adsorption and reaction, Thin Solid Films, Volume 594, Part A, Pages 30–34 doi: 10.1016/j.tsf.2015.10.003. |
| [35] | Kliche, G.; Popovic, Z. V. Far-infrared spectroscopic investigations on CuO, Phys. Rev. B (1990), 42, 10060−10066. |
| [36] | HF Goldstein, Kim D, Yu PY, Bourne LC (1990) Raman study of CuO single crystals, Phys Rev B 41: 7192. |
| [37] | P. K. Ooi, S. S. Ng, M. J. Abdullah, H. Abu Hassan, Z. Hassan (2013) Effects of oxygen percentage on the growth of copper oxide thin films by reactive radio frequency sputtering, Materials Chemistry and Physics 140 (1): 243-248. |
| [38] | R. Shabu, A. Moses Ezhil Raj, C. Sanjeeviraja, C. Ravidhas (2015) Assessment of CuO thin films for its suitablity as window absorbing layer in solar cell fabrications, Materials Research Bulletin 68: 1–8. |
| [39] | S. Karthick Kumar, S. Suresh, S. Murugesan, Samuel Paul Raj (2013) CuO thin films made of nanofibers for solar selective absorber applications, Solar Energy. 94: 299–304. |
| [40] | J. Tauc (Ed), Amorphous & Liquid Semi-conductors (1974), Plenum Press, New York, NY. |
| [41] | G. Papadimitropoulos, N. Vourdas, V. Em. Vamvakas, D. Davazoglou (2005) Deposition and characterization of copper oxide thin films, Journal of Physics: Conference Series 10: 182–185, doi:10.1088/1742-6596/10/1/045. |
| [42] | Addison. (1956) Wesley Publishills Ca., Inc. Reading, Mass. |
| [43] | A. Ashour, M. A. Kaid, N. Z. El-Sayed and A. A. Ibrahim (2006) Physical properties of ZnO thin films deposited by spray pyrolysis technique, Applied Surface Science 252: 7844-7848. |
| [44] | K. S. Wanjala, W. K. Njoroge, N. E. Makori, J. M. Ngaruiya (2016) Optical and Electrical Characterization of CuO Thin Films as Absorber Material for Solar Cell Applications, American Journal of Condensed Matter Physics 6 (1): 1-6. |
APA Style
Mehdi Dhaouadi, Mohamed Jlassi, Imen Sta, Islem Ben Miled, George Mousdis, et al. (2018). Physical Properties of Copper Oxide Thin Films Prepared by Sol–Gel Spin–Coating Method. American Journal of Physics and Applications, 6(2), 43-50. https://doi.org/10.11648/j.ajpa.20180602.13
ACS Style
Mehdi Dhaouadi; Mohamed Jlassi; Imen Sta; Islem Ben Miled; George Mousdis, et al. Physical Properties of Copper Oxide Thin Films Prepared by Sol–Gel Spin–Coating Method. Am. J. Phys. Appl. 2018, 6(2), 43-50. doi: 10.11648/j.ajpa.20180602.13
AMA Style
Mehdi Dhaouadi, Mohamed Jlassi, Imen Sta, Islem Ben Miled, George Mousdis, et al. Physical Properties of Copper Oxide Thin Films Prepared by Sol–Gel Spin–Coating Method. Am J Phys Appl. 2018;6(2):43-50. doi: 10.11648/j.ajpa.20180602.13
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Download@article{10.11648/j.ajpa.20180602.13,
author = {Mehdi Dhaouadi and Mohamed Jlassi and Imen Sta and Islem Ben Miled and George Mousdis and Michael Kompitsas and Wissem Dimassi},
title = {Physical Properties of Copper Oxide Thin Films Prepared by Sol–Gel Spin–Coating Method},
journal = {American Journal of Physics and Applications},
volume = {6},
number = {2},
pages = {43-50},
doi = {10.11648/j.ajpa.20180602.13},
url = {https://doi.org/10.11648/j.ajpa.20180602.13},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ajpa.20180602.13},
abstract = {In this study, copper oxide thin films prepared by the sol–gel method, have been deposed onto glass substrates by the spin coating technique. Our target was to study their properties and improve them for photovoltaic use. These properties were optimized by varying the temperature annealing and the molar concentration of the precursor solutions. The effects of the annealing temperature on the structural and optical properties of the thin films are studied. It was found that the film treated at 550°C shows a higher absorbance. Then by using this optimized temperature, CuO thin films of various molar concentrations, were deposited at the same experimental conditions. The structural analysis by X- ray diffraction (XRD) shows that all the samples are polycrystalline with monoclinic crystal structure. Raman scattering measurements of all thin films confirms the structure of CuO. The optical properties of the films were characterized by UV–Visible–NIR spectrophotometry, which shows that the films show high absorbance in the visible region. Their optical band gap decreases from 3.68 to 2.44 eV when the molar concentration of precursor solutions increases from 0.1 to 0.5 M. The electrical measurements show that the resistivity of the films varies slightly from 84 Ω cm to 124 Ω cm as the molar concentration increases.},
year = {2018}
}
TY - JOUR T1 - Physical Properties of Copper Oxide Thin Films Prepared by Sol–Gel Spin–Coating Method AU - Mehdi Dhaouadi AU - Mohamed Jlassi AU - Imen Sta AU - Islem Ben Miled AU - George Mousdis AU - Michael Kompitsas AU - Wissem Dimassi Y1 - 2018/01/29 PY - 2018 N1 - https://doi.org/10.11648/j.ajpa.20180602.13 DO - 10.11648/j.ajpa.20180602.13 T2 - American Journal of Physics and Applications JF - American Journal of Physics and Applications JO - American Journal of Physics and Applications SP - 43 EP - 50 PB - Science Publishing Group SN - 2330-4308 UR - https://doi.org/10.11648/j.ajpa.20180602.13 AB - In this study, copper oxide thin films prepared by the sol–gel method, have been deposed onto glass substrates by the spin coating technique. Our target was to study their properties and improve them for photovoltaic use. These properties were optimized by varying the temperature annealing and the molar concentration of the precursor solutions. The effects of the annealing temperature on the structural and optical properties of the thin films are studied. It was found that the film treated at 550°C shows a higher absorbance. Then by using this optimized temperature, CuO thin films of various molar concentrations, were deposited at the same experimental conditions. The structural analysis by X- ray diffraction (XRD) shows that all the samples are polycrystalline with monoclinic crystal structure. Raman scattering measurements of all thin films confirms the structure of CuO. The optical properties of the films were characterized by UV–Visible–NIR spectrophotometry, which shows that the films show high absorbance in the visible region. Their optical band gap decreases from 3.68 to 2.44 eV when the molar concentration of precursor solutions increases from 0.1 to 0.5 M. The electrical measurements show that the resistivity of the films varies slightly from 84 Ω cm to 124 Ω cm as the molar concentration increases. VL - 6 IS - 2 ER -
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