STUDIES ON CHEMICALLY DEPOSITED FILMS OF BISMUTH SULFIDE (Bi 2 S 3 ) SIHAM MAHMOUD

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ISSN 1330 0008 CODEN FIZAE4 STUDIES ON CHEMICALLY DEPOSITED FILMS OF BISMUTH SULFIDE (Bi 2 S 3 ) SIHAM MAHMOUD Physics Department, N.R.C., Cairo, Egypt Received 28 March 1996 Revised manuscript received 19 August 1996 UDC 538.975 PACS 68.60.-p The chemical method for deposition of bismuth sulfide (Bi 2 S 3 ) thin films is presented. For the deposition, the triethanolamine complex of bismuth nitrate was allowed to react with aqueous thiourea solution. Good quality (very uniform, reproducible, tightly adherent, specularly reflecting and crack free) deposits are obtained. Micro structural characterizations were carried out by X ray diffraction (XRD) and scanning electron microscope (SEM) in order to study the crystallinity and the surface topography of the films. The studies establish that bismuth sulfide thin films become weak crystalline phase upon annealing in air near 393 K and remain stable up to 573 K. The SEM photographs reveal that crystal size and perfection increase when increasing the thickness of the film. The thermal stability of the powder samples was studied also, using a Shimadzu DSC 50 scanning calorimeter. From the electrical measurements, an activation energy of 0.155 ev was obtained in the temperature range of 300 K to 363 K. The conduction above 363 K was found to be intrinsic with a band gap of 1.38 ev. 1. Introduction Binary semiconductors of the type V 2 VI 3 have been receiving considerable attention in recent years because of the possibility of their utilization in the fabrication of solar energy converters. Hence, it is of interest to study in detail the various properties of some of the members of this family. Bismuth sulfide, which has a large band gap, appears to be a suitable material for solar applications and FIZIKA A 5 (1996) 3, 153 162 153

has been used as liquid junction solar cells [1 3]. Bismuth sulfide (Bi 2 S 3 ) is isomorphic, having orthorhombic lattice with four molecules per unit cell of lattice constants a 0 = 11.13 10 10 m, b 0 = 11.27 10 10 m and c 0 = 3.97 10 10 m [4]. An electroless method of chemical deposition of thin films is a relatively inexpensive, simple, and convenient technique for the preparation of large area V 2 VI 3 compounds. This method has several advantages over other conventional techniques [5,6]. The chemical deposition of Bi 2 S 3 thin films was reported earlier by other authors [7,8]. All the resulting specimens of the previous work were polycrystalline, with small grains, and metallographic examination, after the samples had been heated in the course of Hall and resistivity measurements, showed a second phase. This is probably a bismuth rich phase since sulfur had been lost in the zoning [7,8]. In this paper, the results of a set of systematic experiments made on the growth of Bi 2 S 3 films by chemical method is presented. The effects of bath parameters on the film thickness and properties of the films are investigated. All the prepared films are examined before and after their thermal treatment by scanning electron microscope(sem) and X ray diffraction(xrd). The annealing treatment was used to modify the composition of the film. 2. Experimental procedure Bismuth sulfide Bi 2 S 3 thin films have been prepared by chemical deposition process by allowing the triethanolamine complex of Bi 3+ to react with S 2 ions, which are released slowly by the dissociation thiourea [5 9]. The detailed procedure is: 20 ml of 0.01M freshly prepared solution of Bi 3+, obtained by triturating bismuth nitrate (Bi(NO 3 ) 3 5H 2 O) with triethanolamine, 30 ml 1M thiourea solution and 1 ml (14 N) aqueous ammonia were mixed together in a glass beaker and diluted with distilled water. The ph of the solution was adjusted to around 9.5. The glass substrates were cleaned and kept immersed in the reaction mixture by means of a specially designed substrate holder. The substrate holder was attached to a constant speed motor. The container is placed into a water bath at different temperatures (353 K, 363 K and 373 K) for 1 hour and then kept at room temperature about 4 hours. Uniform films of Bi 2 S 3 are obtained on the glass substrates. The powder and the deposited thin films are then taken out, washed with doubly distilled water and dried in air. The thickness of the thin films was measured using the weighing method. The thermal analyses of the Bi 2 S 3 powder were done by means of Shimadzu DSC 50 scanning calorimeter. The surface morphology of the films and their structure were studied with a JOEL model JSM T 20 scanning electron microscope, and Philips Pw 1390 X ray diffractometer. The electrical resistance of the sample was measured directly by using Keithley 617 programmable electrometer having an input resistance of 10 16 Ω. The optical density is studied by double beam scanning spectrophotometer type UV 3101 Pc from Shimadzu. 3. Results and discussion The deposition temperature, time and ph of the solution play very important roles in producing high quality samples. The chemical deposition of the thin 154 FIZIKA A 5 (1996) 3, 153 162

bismuth sulfide (Bi 2 S 3 ) requires a slow release of Bi 3+ and S 2 ions in an aqueous medium. These ions then condense on a substrate placed in the solution. The deposition process follows an ion by ion condensation on the substrate. The films obtained are nearly stoichiometric. All films were deposited on glass substrates. In the solution growth method for deposition of thin films, the adsorption of metal ions on the surface of the substrate is an important step which forms the nucleation centers of microcrystals of chalcogenides. In the case of glass substrates, the silicate groups on the surface in an alkaline medium facilitate the strong adsorption of metal ions. The following chemical reactions lead to the formation of Bi 2 S 3 ; 1. Ammonia hydrolyses in water to give OH according to the reaction NH 3 +H 2 O NH + 4 +OH. (1) 2. Dissociation of the thiourea in an alkaline medium S = C / \ +OH CH 2 N 2 +H 2 O+HS. (2) 3. Formation of sulfide ions HS +OH S 2 +H 2 O. (3) 4. The overall reaction is 2Bi[N(CH 2 CH 2 OH) 3 ] 3+ +3 S = C / \ +6OH 3 O = C / +Bi \ 2 S 3 +2[N(CH 2 CH 2 OH) 3 ]+3H 2 O. (4) 3.1. Structural analysis Figures 1 and 2 give the XRD patterns of the bismuth sulfide powder and of thin samples annealed in different conditions. The absence of sharp peaks in the diffractograph of the non heated sample (Fig. 1a) shows that the Bi 2 S 3 compound FIZIKA A 5 (1996) 3, 153 162 155

Fig. 1. XRD patterns of Bi 2 S 3 powder samples deposited at bath temperature of 373 K. a) as deposited, b) annealed at 523 K for 15 min and c) annealed at 393 K for 5 h. Fig. 2. XRD patterns of Bi 2 S 3 thin films at different heat treatment (bath temperature of 373 K and time of 50 min): a) as deposited, b) annealed at 523 K for 15 min, c) annealed at 523 K for 30 min, d) annealed at 573 K for 15 min, e) annealed at 573 K for 30 min and f) annealed at 393 K for 5 h. 156 FIZIKA A 5 (1996) 3, 153 162

is nearly amorphous. A very well defined transition to the crystalline state is observed in the powder samples after annealing in air. The identification of the peaks with the help of the JCPDS (17 320) powder diffraction file confirmed the formation of Bi 2 S 3. A weak crystalline phase was also observed in deposited thin films (Fig. 2) and this behaviour indicates that the amorphous to crystalline transformation is taking place in the film when annealed near 393 K. The above behaviour is also evident in the optical density curve in Fig. 3, where the absorption edge is shifted to a lower wavelength. This behaviour is in a good agreement with the results of other investigators [8,10,11]. Fig. 3. Optical density of chemically deposited Bi 2 S 3 films of thickness 860 nm. 1) non heated, 2) heated at 523 K 3) heated at 573 K. 3.2. Differential scanning calorimetry analysis The DSC curve shown in Fig. 4 for the powder sample indicates an exothermic process at 230 C which can be attributed to the growth of grain size. This is consistent with the amorphous to crystalline transition in chemically deposited bismuth sulfide (powder) sample, as already indicated in the XRD spectra. Also, in the DSC curve appeared another exothermic peak at 441 C. Nair et al. [10] demonstrate that at higher annealing temperatures (greater than 300 C) there occurs a transformation to another crystalline state, distinctly different from that of bismuthnite. 3.3. Effect of bath parameters Figure 5 shows the growth kinetics of Bi 2 S 3 films with the time of deposition at different bath temperatures. At a particular temperature, Bi 2 S 3 will be deposited FIZIKA A 5 (1996) 3, 153 162 157

Fig. 4. DSCcurve( T vs. T)forthepowderBi 2 S 3 sample; heatingrate10 C/min. Fig. 5. Thickness of Bi 2 S 3 film as a function of deposition time at 1) 353 K, 2) 363 K and 3) 373 K. if the ionic product (IP) of Bi 3+ and S 2 exceeds the solubility product (SP) of Bi 2 S 3. It is noticed from the curve that the initial growth rate is fast and then the growth slows down until a final thickness is reached. At low temperature ( 353 K), the rate of formation of Bi 2 S 3 on the substrate is probably more or less comparable to the rate of release of the corresponding ions, thus resulting in maximum 158 FIZIKA A 5 (1996) 3, 153 162

utilization of the ions and greater final thickness. At bath temperature ( 373 K), the concentrations of released Bi 3+ and S 2 increase considerably, which results in higher rates of deposition. The deposition rate of Bi 2 S 3 also increases due to kinetic energy of the ions and consequent increase of interaction between them. However, the rates of release Bi 3+ and S 2 ions seem to become considerably larger than the rate of formation of Bi 2 S 3 at the surface nucleation centers. Hence, only a fraction of the ions is utilized for film formation, resulting in a lower final thickness. The unutilized ions precipitate via volume nucleation centers. This behaviour is in a good agreement with results of other authors [12,13]. 3.4. Scanning electron microscope The surface morphology of a typical Bi 2 S 3 films is shown in Figs. 6 and 7. The figures demonstrate the effect of the dipping time and heat treatment on the morphology of the films. The electron micrographs of the non heated samples demonstrate the increase in the crystallite size with increase of the dipping time (Fig. 6). Also, the film contains random distribution of small crystallites which are formed at certain preferred sites on glass substrate. During the initial period, a thin film formation takes place and then a single crystallite overgrowth starts predominating. The size and abundance of these single crystallites depend on the deposition parameters [14,15]. By heating the samples to different temperatures (523 K and 573 K), very different structures become apparent. The surface of the film becomes slightly rough with structure characteristic of a collection of crystallites which have grown to different sizes. Fig. 6. Scanning electron micrograph of Bi 2 S 3 films at different dipping time and their thickness are; a) d 700 nm, 10 500x, 20 min, b) d 780 nm, 10 500x, 30 min, c) d 830 nm, 10 500x, 40 min, and d) d 860 nm, 10 500x, 50 min. FIZIKA A 5 (1996) 3, 153 162 159

Fig. 7. Scanning electron micrograph of Bi 2 S 3 films at different annealing temperature; a) d 860 nm, heated at 523 K for 15 min, 6000x and b) d 860 nm, heated at 573 K for 15 min, 6000x. 3.5. Electrical characterization Figure 8 shows the behaviour of the resistance for the as deposited films of different dipping time at room temperature. The figure demonstrates that, as the film thickness increases, the resistance decreases. This behaviour may be due to crystallite size [16] which was observed by scanning electron microscopy. The resistance was measured by a Keithley 617 electrometer. Fig. 8. The variation in resistance with film thickness. The DC resistance of the deposited Bi 2 S 3 was measured in the temperature range 300 K 569 K for heating cycle (Fig. 9). The contacts were made laterally by silver paste. The activation energy (0.155 ev) in the low temperature region (Fig. 9) is the energy required for a transition between the defect level and the valence band or conduction band. This value is in a good agreement with the value 0.16 ev reported by Deshmukh et al. [6]. At sufficiently high temperature, intrinsic 160 FIZIKA A 5 (1996) 3, 153 162

conductivity starts and electron transitions from the valence band to the conduction band take place. Hence, the conductivity in the high temperature region (Fig. 9) is due to the band to band transitions. The energy of 1.38 ev was deduced for the band gap, E g, of the Bi 2 S 3 film. This value agrees with the value of 1.38 ev reported by other authors [4,17]. Fig. 9. log R vs. 1/T for a layer 680 nm thick (heating cycle). 4. Conclusion Chemically deposited thin films of bismuth sulfide (Bi 2 S 3 ), deposited on glass substrate, have been studied to obtain information about their structure, thermal stability and electrical properties. The technique offers a way to avoid the clumsy and time consuming processes involved in the deposition of this material by other techniques. From the electrical measurements at lower temperatures, the resistivity change is dominated by transition between conduction or valence band and some FIZIKA A 5 (1996) 3, 153 162 161

defect related level in the gap. The band gap E g in the high temperature region is 1.38 ev. Acknowledgement The author would like to acknowledge kind cooperation and interest of Prof. A. H. Eid. References 1) D. D. Miller and A. Heller, Nature 262 (1976) 280; 2) L. M. Peter, J. Electroanal. Chem. 98 (1979) 49; 3) P. K. Mahapatre and C. B. Roy, Sol. Cells 7 (1982 1983) 225; 4) J. Block, E. M. Conwell, L. Seigle and C. W. Spenser, J. Phys. Chem. Solids 2 (1957) 240; 5) C. V. Suryanar, A. S. Lakshmanan, V. Subramanion and R. K. Kumar, Bull. Electrochem. 2 (1986) 57; 6) L. P. Deshmukh, A. B. Plawe and V. S. Swant, Sol. Energy Mater. 20 (1990) 341; 7) P. Pramanik and R. N. Bhattacharya, J. Electrochem. Soc. 127 (1980) 2087; 8) S. Biswas, A. Mondal, D. Mukherjee and P. Pramanik, J. Electrochem. Soc. 133 (1986) 48; 9) R. N. Bhattacharya and P. Pramnik, J. Electrochem. Soc. 129 (1982) 332; 10) P. K. Nair, M. T. S. Nair, M. K. K. Pathirana, A. Zingero and A. Meyers, J. Electrochem. Soc. 140 (1993) 754; 11) P.K.Nair, J.Compos, A.Sanchez, L.BanosandM.T.S.Nair, Semicond. Sci. Technol. 6 (1991) 393; 12) P. K. Nair and M. T. S. Nair, Semicond. Sci. Technol. 7 (1992) 239; 13) A. Mondal and P. Pramanik, Sol. Energy Mater. 7 (1983) 431; 14) M. T. S. Nair and P. K. Nair, Semicond. Sci. Technol. 5 (1990) 1225; 15) P. K. Nair, M. T. S. Nair and J. Compos, Sol. Energy Mater. 15 (1987) 441; 16) B. B. Nayak and H. N. Acharya, J. Mater. Sci. 21 (1986) 46; 17) J. Lukose and B. Pradeep, Solid State Communication 78 (1991) 535. ISTRAŽIVANJE KEMIJSKI TALOŽENIH FILMOVA BIZMUT SULFIDA (Bi 2 S 3 ) Proučavanjem kemijski taloženih tankih slojeva bizmut sulfida na staklenom substratu dobiveni su podaci o njihovoj strukturi, termičkoj stabilnosti i električnim svojstvima. Odredene su aktivacijske energije nositelja naboja u području ekstrinsične i intrinsične vodljivosti. 162 FIZIKA A 5 (1996) 3, 153 162

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