FOTOVOLTAİK GÜNEŞ PİLLERİNDE KULLANILAN ZNO VE CUO FİLMLERİNİN SILAR YÖNTEMİ İLE ÜRETİLMESİ VE KARAKTERİZASYONU

Bu çalışmada ZnO ve CuO filmleri pratik ve ekonomik bir teknik olan SILAR (Successive Ionic Layer Adsorption and Reaction) yöntemi ile üretilmiştir. Filmlerin yapısal, optik, elipsometrik, yüzeysel ve elektrik özellikleri sırası ile XRD, UV spektroskopisi, Spektroskopik Elipsometre (SE), Atomik Kuvvet Mikroskobu (AFM) ve dört-uç tekniği kullanılarak incelenmiştir. Filmlerin yasak enerji aralıkları, optik metot kullanılarak 3,22 eV-1,72 eV olarak hesaplanmıştır. Spektroskopik elipsometre (SE) tekniği ile filmlerinin kalınlıkları ve bazı optik sabitleri (sönüm katsayısı ve kırılma indisi) belirlenmiştir. Ayrıca, filmlerin üç boyutlu yüzey görüntüleri incelenmiş ve ortalama yüzey pürüzlülük değerleri 38 nm and 60 nm olarak tespit edilmiştir. Filmlerin elektriksel özdirenç değerleri ve iletim tipi sırasıyla dört-uç metodu ve sıcak uç tekniği kullanılarak belirlenmiştir.

Anahtar Kelimeler:

Fotovoltaik güneş pilleri, ZnO ve CuO filmleri, SILAR, XRD, SE, AFM

The Production of ZnO and CuO Films by SILAR Method andCharacterization for Use in Photovoltaic Solar Cells

In this study; ZnO and CuO films were produced by SILAR (Successive Ionic Layer Adsorption and Reaction) technique which is a practically and economic. The films of structural, optical, ellipsometric, surface and electrical properties were determined by XRD diffactometer, UV spectrophotometer, Spectroscopic Ellipsomery (SE), Atomic Force Microscope (AFM), Four-Probe, respectively. The band gaps of films were calculated as 3.22 eV-1.72 eV using optic method. The thickness and some optic constants (extinction coefficient and refractive index) of films were investigated by SE. Also, the three dimensional surface images of films were obtained and the average surface roughness values were determined as 38 and 60 nm. The electrical resistivity values and conduction mechanism were investigated by using four-probe and hot-probe technique, respectively

Keywords:

Photovoltaic solar cells, ZnO and CuO films, SILAR, XRD, SE, AFM,

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Terasako T., Murakami T., Hyodou A., Shirakata S. 2015. Structural and electrical properties of CuO films and n-ZnO/p-CuO prepared deposition based technique, Solar
Energy Materials & Solar Cells, Cilt. , 1016/j.solmat.2014.08.023 bath s. –79. DOI:
Fahrenbruch A.L. 1997. II-VI Compounds in Journal of Crystal s. Growth, Cilt. , 91. assited growth and DOI:
Hu X., Gao F., Xiang Y., Wu H., Zheng X., Jiang J., Li J., Yang H., Liu S. 2016.
Influence of oxygen pressure on the structural and electrical properties of CuO thin films prepared by pulsed laser deposition, Materials Letters, Cilt. 176, s. 282-284. DOI:10.1016/j.matlet.2016.04.055
Saadaldin N., Alsloum M.N., Hussain N. 2015. Preparing of Copper oxides
Thin Films by Chemical Bath Deposition (CBD) for Using in Environmental Application, Energy Procedia, Cilt. 74, s. 1459-146. DOI: 1016/j.egypro.2015.07.794
Mbulanga C. M., Urgessa Z. N., Tankio Djiokap S.R., Botha J.R., Duvenhage M. M., Swart H. C. 2016. Surface characterization of ZnO nanorods grown by chemical bath deposition,
Physica B: Condensed Matter, Cilt. , 1016/j.physb.2015.07.016 DOI:
Bedia A., Bedia F.Z., Aillerie M., Maloufi N., Benyoucef B. 2015.
Morphological and optical properties of ZnO thin films prepared by spray pyrolysis on glass substrates at various temperatures for integration in solar cell, Energy Procedia, Cilt. , 1016/j.egypro.2015.07.740 DOI:
Cachoncinlle C., Hebert C., Perrière J., Nistor M., Petit A., Millon E. 2015.
Random lasing of ZnO thin films grown by pulsed-lase deposition, Applied Surface Science, Cilt. 336, s. 107. 1016/j.apsusc.2014.09.186
Jayaraman V. K., Kuwabara Y. M., Álvarez A. M., Amador María de la luz O. 2016. Importance of substrate rotation speed on the growth of homogeneous ZnO thin films by reactive sputtering, Materials Letters, Cilt. 1016/j.matlet.2016.01.088 4. DOI:
Maleki-Ghaleh H., Shahzadeh M., Hoseinizadeh S. A., Arabi A., Aghaie E., Siadati M. H. 2016. Evaluation of the behavior of nano-structured ZnO films electrodepositon process, Materials
Letters, Cilt. 169, s. 140-143. DOI: 1016/j.matlet.2016.01.090 br
Armelao L., Barreca D., Bertapelle M., Bottaro G., Sada C., Tondello E. A sol-gel approach to nanophasic copper oxide thin films, Thin Solid Films, Cilt. 442, No. 1–2, s. 48-52. DOI: 10.1016/S0040- (03)00940-4 Gould R.D., Rahman M.S. 1981.
Power-law currents in some ZnO- Sn composite materials, Applied Physics, Cilt. 14, s. 79-89.DOI: 1088/0022-3727/14/1/011
Chen A., Long H., Li X., Li Y., Yang G., Lu P. 2009. Controlled growth and characteristics of single-phase
Cu2O and CuO films by pulsed laser deposition, Vacuum, Cilt. 83, s. –930. 1016/j.vacuum.2008.10.003 DOI:
Kumar A. K., Murugesan S., Suresh S., Raj S. P. 2013. Nanostructured
CuO thin films prepared through sputtering for solar selective absorbers, Journal of Solar Energy, Article ID 147270, s.1-6. DOI: 1155/2013/147270
Maruyama T. 1998. Copper Oxide
Thin Films Prepared from Copper Dipivaloylmethanate and Oxygen by Chemical Vapor Deposition, Japanese Physics Cilt. 37 (7), s. 4099-4102. DOI: 10.1143/JJAP.37.4099
Ray S. C. 2001. Preparation of copper oxide thin film by the solgel-like dip technique and study of their structural and optical properties, Solar Energy Materials
& Solar Cells, Cilt. 68, s. 307-312. DOI: (00)00364-0 Al-Kuhaili M. F.
Characterization of copper oxide thin films deposited by the thermal evaporation of cuprous oxide (Cu2O), Vacuum, Cilt. 82, s. 623– 1016/j.vacuum.2007.10.004 DOI:
Muiva C. M., Maabong K., Moditswe C. 2016. CuO nanostructured thin films synthesised by chemical bath deposition deposited by successive ionic layer adsorption chemical techniques, Thin Solid Films, Cilt. , layers reaction and pyrolysis s. 54. DOI: 1016/j.tsf.2016.07.061
Thankalekshmi R. R., Rastogi A. C. Synthesis and properties of Zn(Cu-Mn)O semiconductor chemical technique, Journal of Analytical and Applied Pyrolysis, Cilt 107, s. 183- 1016/j.jaap.2014.02.020 by DOI:
Singh I., Kaur G., Bed R. K. 2011. CTAB characterization of nanocrystalline
CuO films by ultrasonic spray pyrolysis technique, Applied Surface Science, Cilt. 257 (22), s. 9554. 1016/j.apsusc.2011.06.061
Morales J., Sanchez L., Martin F., Romos-Barrado J.R., Sanchez M. Nanostructured CuO Thin Film Electrodes Prepared By Spray Pyrolysis: A Simple Method For Enhancing The Electrochemical Performance of CuO in Lithium Cells, Electrochimica Acta, Cilt. 49, s. 4589. DOI:10.1016/j.electacta.2004.05.0
Derin H., Kantarli K., 2002. Optical characterization of thin thermal oxide ellipsometry, Applied Physics A, Cilt. 1007/s003390100989 by , –395. DOI:
Papadimitropoulos G., Vourdas N., Vamvakas V. E., Davazoglou D. characterization of copper oxide thin films, Journal of Physics: Conference Series, Cilt. 10, s. 182– /10/1/045 and DOI: 1088/1742
Sasagawa M., Nosaka Y. 2002.
Electrochemical evaluation of the roles of chelating reagents in Cd ion adsorption on CdS surface for the adsorption and reaction (SILAR) deposition, Electroanalytical Chemistry, Cilt. , 1016/S0022-0728(02)01213-5 DOI:
Patil U. M., Gurav K. V., Joo Oh-Shim, Lokhande C. D. 2009. Synthesis of photosensitive nanograined TiO2 thin films by SILAR method,
Journal of Alloys and Compounds, Cilt. 478, No. 1, s. 711–715. DOI:10.1016/j.jallcom.2008.11.160 Gokul B., Matheswaran P.,
Sathyamoorthy R. 2013. Influence of annealing on ohysical properties of CdO thin films prepared by
SILAR method, Journal of Materials Science & Technology, Cilt. 29, No. , s. 21. DOI: 1016/j.jmst.2012.11.015
Tatar D. Spray pyrolysis yöntemi ile farklı altlık sıcaklığında elde edilen Sn2O ve SnO2:F ince filmlerin bazı fiziksel sıcaklığının etkisinin araştırılması, Doktora Tezi, Atatürk Üniversitesi Fen Bilimleri Enstitüsü, 2015. altlık
Connoly R. 2003. Introduction to x- ray powder diffraction, Springer.
Cullity B. D. 2001. Stock S.R.
Elements of X-ray diffraction (3rd ed.), Prentice Hall. Joseph B., Gopchandran K.G., Thomas P.V., Koshy P., Vaidyan, V. K. 1999. A study on the chemical spray deposition of zinc oxide thin films and their structural and electrical
Chemistry and Physics, Cilt. 58, s. DOI: (98)00257-0 Materials 77. 1016/S0254
Williamson G. K., Smallman R. E. III. Dislocation densities in some annealed and cold-worked metals from measurements on the X-ray debye-scherrer spectrum, Phil Mg., Cilt. 1, No.1, s. 134-34. DOI:10.1080/1478643560823807
Zhao Z., Morel D. L., Ferekides C. S. properties of thin-doped CdO films deposited metalorganic deposition, Thin Solid Films, Cilt. , 1016/S0040-6090(02)00344-9 DOI: DOI:
Vigil O., Vaillant L., Cruz F., Santana G., Morales-Acevedo A., Contreras- Puente G. 2000. Spray pyrolysis deposition of cadmium-zinc oxide thin films, Thin Solid Films, Cilt. 362, 1016/S0040-6090(99)01061-5 DOI:
Bayansal F., Şahin B., Yüksel M., Çetinkara H.A. 2013. SILAR-based growth o nanostructured CuO thin films containing saccharin as assistive,
Material Letters, Cilt. 98, s. 197- 1016/j.matlet.2013.02.030 DOI:
Akaltun Y. 2015. Effect of thickness on the structural and optical properties of CuO thin films grown by adsorption and reaction, Thin
Soldis Films, Cilt. 594, s. 30-34. DOI: 1016/j.tsf.2015.10.003 layer
Jayakrishnan R., Kurian A. S., Vrun G. N., Joseph M. R. 2016. Effect of vacuum photoconductivity of CuO thin films grown using sequential ionic layer adsorption
Chemistry and Physics, Cilt. 180, s. 155. DOI:10.1016/j.matchemphys.2016. 055 on the Material
Rajkumar P.V., Ravichandran K. , Baneto M. , Ravidhas C., Sakthivel B., Enhancement electrical properties of SILAR deposited ZnO thin films through fluorine annealing applications, Materials Science in Semiconductor Processing, Cilt. 35, s. 1016/j.mssp.2015.03.010 and doping and vacuum for photovoltaic –196. DOI:
Rahman M. A., Phillips M. R., That- Ton C. 2017. Efficient multi- coloured Li-doped ZnO thin films fabricated by spray pyrolysis,
Journal of Alloys and Compounds, Cilt. , 1016/j.jallcom.2016.08.242 DOI:
Dhruvashi, Shishodia P. K. 2016.
Effect of cobalt doping on ZnO thin films deposited by sol-gel method, Thin Solid Films, Cilt. 612, s. 55-60. DOI: 10.1016/j.tsf.2016.05.028
Chand P., Gaur A., Kumar Ash., Gaur U. K. 2014. Structural and optical study of Li doped CuO thin films on
Si (1 0 0) substrate deposited by pulsed laser deposition, Applied Surface Science, Cilt. 307, s. 280- 1016/j.apsusc.2014.04.027 DOI:
Wang F., Wang Y., Chen L., Wei B., Hao S. 2016. Effects of surface oxygen synthesized by plasma enhanced chemical
Material Letters, Cilt. 182, s. 52-54. DOI: 10.1016/j.matlet.2016.06.082
Baviskar K. P., Nikam P. R., Gargote S. S., Ennaoui A., Sankpal B. R. Controlled synthesis of ZnO nanostructures morphologies via simple solution chemistry, Journal of Alloys and Compounds, Cilt. 551, s. 233-242. DOI:10.1016/j.jallcom.2012.10.052