Microsoft Word - ETASR_V11_N4_pp7393-7398 Engineering, Technology & Applied Science Research Vol. 11, No. 4, 2021, 7393-7398 7393 www.etasr.com Ho & Anand: The Influence of Bath Temperature on the Properties of SILAR Deposited Cobalt … The Influence of Bath Temperature on the Properties of SILAR Deposited Cobalt Selenide Thin Films Soon Min Ho Centre for American Education INTI International University Putra Nilai, Negeri Sembilan, Malaysia soonmin.ho@newinti.edu.my T. Joseph Sahaya Anand Faculty of Mechanical and Manufacturing Engineering Technology, Universiti Teknikal Malaysia Melaka Durian Tunggal, Malacca, Malaysia anand@utem.edu.my Abstract-In this paper, cobalt selenide thin films have been deposited onto glass slides with the SILAR method under various bath temperatures. The structure, optical properties, and morphology of thin films were investigated. The X-ray diffraction patterns confirmed that the number of peak intensities increased with increasing bath temperature. From the AFM images, bigger sizes and thicker films were observed for the films prepared at 80°C. The average grain size was estimated to be 0.2µm, 0.15µm, and 0.25µm when the bath temperature was 40°C, 50°C, and 80°C respectively. The highest absorbance value was observed for films prepared at 80°C. The band gap values range from 2eV to 2.4eV. Keywords-thin films; cobalt selenide; semiconductor; band gap; solar cells; SILAR technique I. INTRODUCTION Growing fuel prices and the fast depleting of conventional energy sources lead to the necessity of the investigation on sustainable and efficient energy sources. Renewable energy has been suggested as a viable approach. Presently, many research groups have focused on solar energy as the most promising renewable energy to cater the future energy demand due to its abundance and inexhaustibility [1, 2]. Due to the effort of finding new materials, Transition Metal Chalcogenides (TMCs) are proposed as the most satisfactory semiconductor materials for Photo Electro Chemical (PEC) application. TMCs are a combination of transition metals and chalcogenides (group 16), MX2 (M: Cd, Mo, Co, Zn, Cu, Ni, Fe, Sn, etc., X: S, Se, and Te). TMCs possess excellent optical, electrical, and semiconductor properties, especially in the thin film form [3]. This advancement has motivated many researchers to investigate TMC materials namely, CdS [4], CdSe [5], ZnS [6], SnS [7], ZnSe [8], CuInTe2 [9], CuInSe2 [10], ZnTe [11], Ni3Pb2S2 [12], CuTe [13], and Cu4SnS4 [14]. Chalcogenide thin films can be fabricated by electrodeposition, spray pyrolysis, electrochemical deposition [15], and sputtering [16]. One attractive method for producing cobalt chalcogenide thin films, due to the possibility of large area deposition at low cost, is the Successive Ionic Layer Adsorption and Reaction (SILAR) deposition method. It is a cost-effective method that can be controlled easily [17, 18]. It is the process of enlarging the thin film by separating the weakly bound elements in the pure water from the surface after immersing the substrate material at certain times and immersing it in cationic and anionic solutions [19, 20]. The SILAR method consists of four steps [21]: dipping into cationic solution, rinsing in de-ionized water, dipping in an ionic solution and rinsing again in de-ionized water. It is shown that cobalt chalcogenides have higher electronegativity, so it is proposed to study the synthesis, growth mechanism, optical and semiconducting properties of these thin films in a more systematic way. Selenium and sulphur (X= S, Se), are non-metal while tellurium (Te) is a metalloid. Hence, the chemical behavior and reaction of sulphur and selenium are similar to telluride. In the present research work, focus is given only to cobalt selenide. The aim of this work is to investigate the influence of bath temperature on the formation of cobalt selenide thin films. The SILAR deposition technique was used to synthesize films for the first time. Characterization of films was carried out by using XRD (X-Ray Diffraction), AFM (Atomic Force Microscopy), and an UV-visible spectrophotometer. Thin films can be used in various fields including solar cells, optical devices, energy storage devices, environmental applications, laser devices, and telecommunications devices. These materials have a great impact on the modern era of technology. Thin films (binary, ternary, quaternary, and penternary compounds) can be produced by physical and chemical deposition techniques [22-24]. The selection of deposition method depends on the production cost, the specific application, the properties of films and available resources. Cobalt sulphide [25-30], cobalt telluride [31-34], and cobalt selenide [35-40] thin films have been synthesized via various deposition techniques. In this work, the SILAR method was selected to produce cobalt selenide films. Staring materials such as cobalt (II) chloride hexahydrate and sodium selenite were used to deposit thin films onto glass substrate for the first time. II. EXPERIMENTAL PART Cobalt (II) chloride hexahydrate (CoCl2.6H2O) and sodium selenite (Na2O3Se) were used without further purification. Microscope glass slide was used as substrate during the deposition process. This substrate was cleaned by acetone and de-ionized water before use. During the deposition process, the glass substrate was immersed in a 0.25M cationic solution (Co2+ ion) with pH=3 for 30s. After rinsing with de-ionized Corresponding author: Soon Min Ho Engineering, Technology & Applied Science Research Vol. 11, No. 4, 2021, 7393-7398 7394 www.etasr.com Ho & Anand: The Influence of Bath Temperature on the Properties of SILAR Deposited Cobalt … water for 10s, it was immersed in 0.25M anionic solution (Se2- ions) with pH=3 for 30s. Then, it was rinsed with de-ionized water for 10s again in order to remove the loose material. The reaction solutions were put in a beaker into the water bath under various temperatures (40, 50, and 80°C). After the deposition process (after 10 cycles), the films were collected, rinsed by de-ionized water, and finally, put in the oven for 24h. The structure of the film was investigated by XRD with a Malvern Panalytical diffractometer (EMPYREAN) equipped with a Cu Kα (λ=0.15418nm) radiation source. Data were collected by step scanning from 10° to 80° with a step size of 0.02° (2θ). Surface morphology, thickness, and roughness were examined by recording the AFM images with Bruker. The mode was Scanasyst peak force tapping. The cantilever was scanasyst-air (material: silicon tip on nitride lever) with spring constants of 0.4N/m and resonance frequencies of 70kHz. The optical properties of the films were studied with the Perkin Elmer UV/Vis Lambda 35 Spectrophotometer. The band gap energy values were calculated based on the absorption data. III. RESULTS AND DISCUSSION AFM measurements were carried out in order to investigate surface roughness and surface topology. The surface roughness was studied on the Rq value which is defined as the root mean square average of height deviation taken from the mean image data plane. Figure 1 shows the AFM images of SILAR deposited cobalt selenide thin films under different bath temperatures. These images were measured over 1µm×1µm scanning range. The films deposited at lower temperatures (40°C and 50°C) indicated uneven morphology in comparison with the ones deposited at higher temperature. Uniformly grained and compact morphological surface was observed at 80°C. These results are consistent with several other studies, indicating that grain grows more compactness and regularity in morphology with increase in temperature [41, 42]. The average grain size (0.2, 0.15, and 0.25µm) and surface roughness (0.0191, 0.0102, 0.0192µm) were reduced from 40 to 50°C and increased at 80°C. On the other hand, we found that film thickness (1.4 to 1.7µm) increased with increasing temperature. The temperature effect on the film thickness has been reported by many researchers [43, 44]. Figure 2 indicates the XRD patterns for the cobalt selenide thin films prepared under various bath temperatures. It can be seen that the XRD patterns exhibited diffraction peaks at 2θ=13°, which can be indexed as reflection from the (111) plane of the cubic structure Co9Se8 compound (films prepared at 40°C and 50°C). Other researchers have reported similar findings (cubic cobalt selenide structure) [45, 46]. An additional peak attributed to the (113) plane became more visible for the films synthesized at 80°C. A sharp diffraction peak can be observed in Figure 2(c) reflecting the better crystallinity of the sample. The obtained XRD patterns were well matched with the standard Joint Committee on Powder Diffraction Standards (JCPDS) (Reference code: 98-004-4857) as indicated in Table I. Based on the JCPDS data, the lattice parameter values are a=b=c=10.431Å. The crystal system, space group and space group number were cubic, Fm-3m and 225 respectively. TABLE I. COMPARISON OF OBSERVED D-SPACING VALUES WITH STANDARD D-SPACING VALUES OF COBALT SELENIDE THIN FILMS. Temperature (°°°°) Reflection plane (hkl) Observed d- spacing values (Å) Standard d- spacing values (Å) 40 111 6.8 6.0 50 111 6.8 6.0 80 111 113 6.8 3.2 6.0 3.1 (a) (b) (c) Fig. 1. AFM images for films prepared at (a) 40°C, (b) 50°C, (c) 80°C. Engineering, Technology & Applied Science Research Vol. 11, No. 4, 2021, 7393-7398 7395 www.etasr.com Ho & Anand: The Influence of Bath Temperature on the Properties of SILAR Deposited Cobalt … (a) (b) (c) Fig. 2. XRD patterns for the films prepared at (a) 40°C, (b) 50°C, (c) 80°C. Figure 3 exhibits the absorbance spectra (at wavelengths from 300 to 1000nm) of cobalt selenide thin films prepared under different bath temperatures. Generally, we observe that all the samples showed high absorption in the visible range, which allows the use of these materials in photo electrochemical and solar cells. The absorbance decreases with increasing wavelength. A similar tendency was also observed in [47, 48]. From Figure 3, we note that the highest absorbance value can be observed for films prepared at 80°C due to increased grain size with thickness. Larger size reduces the reflectivity of incident photon on the film surface [49, 50]. The band gap was calculated by the Stern equation which is a very useful and commonly used method [51-57]. Fig. 3. Optical absorbance spectra of thin films prepared at (a) 40°C, (b) 50°C, (c) 80°C. � � ������ � �/� �� (1) In (1) v is the frequency, h is the Planck’s constant, k is a constant, while n carries the value of either 1 or 4. The n value is 1 for a direct gap material and 4 for indirect gap material. The plot of (Ahν)2 against hν is shown in Figure 4. Extrapolation of the linear portion of the curve to (Ahν)2=0 produces the band gap energy. The band gap increased from 2.1eV (40°C) to 2.4eV (50°C), and dropped to 2eV (80°C) as shown in Figure 4. Other research groups have highlighted similar band gap values (Table II). These cobalt selenide films have been prepared by using different methods including chemical bath deposition, electro deposition, magnetron sputtering method and mechano chemical method. The obtained thin films could be used in solar cell applications because of direct band gap between 1 to 2eV [58, 59]. TABLE II. BAND GAP ENERGY OF COBALT SELENIDE THIN FILMS PREPARED UNDER DIFFERENT DEPOSITION TECHNIQUES Remarks Band gap value (eV) Reference Thin films were produced onto glass substrate by using chemical bath deposition method in the presence of ammonia, cobalt (Ii) acetate and sodium selenosulphite. 1.8 to 3.6 [35] Thin films were synthesized onto tin oxide glass substrate via electro deposition technique in the presence of H2SeO3 and Co(CH3COO)2 solutions. 1.53 [36] Thin films were prepared onto non- conducting micro glass slide through chemical bath deposition method, in the presence of cobalt nitrate, ammonia and sodium selenosulphate. 1.7 [37] Thin films were produced using magnetron sputtering method 1.53 [38] Thin films were synthesized onto tin oxide coated glass by using electrodeposition method. 1.53 [39] Thin films were grown using the mechanochemical method. 1.7 [40] Engineering, Technology & Applied Science Research Vol. 11, No. 4, 2021, 7393-7398 7396 www.etasr.com Ho & Anand: The Influence of Bath Temperature on the Properties of SILAR Deposited Cobalt … (a) (b) (c) Fig. 4. (Ahv)2 curve against (hv) for thin films prepared at (a) 40°C, (b) 50°C, (c) 80°C. IV. CONCLUSIONS The influence of bath temperature on the formation of SILAR deposited cobalt selenide thin films was studied in this paper. The XRD data supported the existence of cubic phase cobalt selenide films. The XRD patterns confirmed that the number of peaks increased with increasing bath temperature. The films prepared at 80°C have higher absorption, crystallinity, and the most homogeneity. Band gap values were observed in the range of 2eV to 2.4eV. ACKNOWLEDGMENT This research work was supported by the INTI International University under INTI Internal Research Grant INTI–CAE-01- 01-2018. REFERENCES [1] T. J. S. Anand, S. Sharir, and S. I. Abd. Razak, "Electrosynthesized transition metal chalcogenide thin films for photoelectrochemical cell applications," Current Topics in Electrochemistry, vol. 21, pp. 131–150, 2020. [2] H. M. M. N. Hennayaka and H. S. 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Girma, "Synthesis and Characterization of aluminum dope zinc sulfide (Al:ZnS) thin films by chemical bath deposition techniques," Journal of Applied Biotechnology and Bioengineering, vol. 8, no. 2, pp. 55–58, 2021. [54] G. Pérez-Hernández et al., "A comparative study of CdS thin films deposited by different techniques," Thin Solid Films, vol. 535, pp. 154– 157, May 2013, https://doi.org/10.1016/j.tsf.2012.11.092. [55] A. Kassim, T. W. Tee, A. H. Abdullah, S. Nagalingam, and H. S. Min, "Deposition and characterization of Cu 4 SnS 4 thin films by chemical bath deposition method," Macedonian Journal of Chemistry and Chemical Engineering, vol. 29, no. 1, pp. 97–103, Jun. 2010, https://doi.org/10.20450/mjcce.2010.178. [56] A. Kassim, M. Y. Rosli, and H. Min, "UV-Visible studies of chemical bath deposited NiSe thin films.," International Journal of Chemical Research, vol. 3, no. 1, pp. 21–26, Jul. 2011, https://doi.org/10.9735/ 0975-3699.3.1.21-26. [57] A. Kassim, S. Nagalingam, W. Tan, H. Min, and D. Teo, "Chemical Bath Deposition of Nickel Sulphide (Ni4S3) Thin Films," Leonardo Journal of Sciences, vol. 16, pp. 1–12, Jan. 2010. [58] H. Soonmin, "Power Conversion Efficiency in Thin Film Solar Cell: A Review," International Journal of Chemical Sciences, vol. 14, no. 1, pp. 143–151, Mar. 2016. [59] T. Sinha, L. Verma, and A. Khare, "Variations in photovoltaic parameters of CdTe/CdS thin film solar cells by changing the substrate for the deposition of CdS window layer," Applied Physics A, vol. 126, no. 11, Oct. 2020, Art. no. 867, https://doi.org/10.1007/s00339-020- 04058-4. AUTHORS PROFILE Soon Min Ho is a professor in INTI International University in Malaysia. He received his Ph.D. in Materials Chemistry at Putra University, Malaysia. He has taught a variety of chemistry courses such as physical chemistry, organic chemistry, general chemistry, chemistry & society over the last ten years. His research areas include chalcogenide metals, activated carbon, wastewater treatment, green chemistry, semiconductors, nano materials, and thin film solar cells. He has authored or co-authored more than 155 articles in Scopus/ISI/international referred journals and successfully produced more than 45 book chapters. He has been appointed as a journal reviewer, editorial board member, and thesis external examiner. T. Joseph Sahaya Anand is an expatriate staff who was born in India on July 30, 1975. As a Physics graduate he completed his PG and M.Phil from St. Joseph’s College, affiliated to Bharathidasan University. He received his Ph.D. in Materials Science from the University of Hong Kong in 2004. He has been awarded with post-doctoral fellowship by the Tohoku University, Sendai Japan during 2004–2005. He is currently a Professor of Materials Science in the Faculty of Mechanical and Manufacturing Engineering Technology. His research interests are materials synthesis and characterization of transition metal chalcogenides and intermetallic aluminides for electronic / semiconductor applications.