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Bath pH Dependence on the Structural and Optical Properties of Chemical Bath Deposited CdS Thin Films

Published online by Cambridge University Press:  01 February 2011

Udaya S. Ketipearachchi
Affiliation:
Center for Materials and Engineering, Cranfield University, RMCS, Shrivenham, Swindon, SN6 6LA, UK
David W. Lane
Affiliation:
Center for Materials and Engineering, Cranfield University, RMCS, Shrivenham, Swindon, SN6 6LA, UK
Keith D. Rogers
Affiliation:
Center for Materials and Engineering, Cranfield University, RMCS, Shrivenham, Swindon, SN6 6LA, UK
Jonathan D. Painter
Affiliation:
Center for Materials and Engineering, Cranfield University, RMCS, Shrivenham, Swindon, SN6 6LA, UK
Michael A. Cousins
Affiliation:
Center for Materials and Engineering, Cranfield University, RMCS, Shrivenham, Swindon, SN6 6LA, UK
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Abstract

High quality CdS thin films made with ultrasonic agitation during chemical bath deposition were investigated. The change in band gap and variation of atomic stacking during the film growth was observed as a function of bath pH. The band gap of as-deposited thin films of CdS was found to be between 2.26 eV and 2.50 eV, the highest being observed when the pH was 9.0. The transition from cubic (β-CdS) to hexagonal (a-CdS) was observed with decreasing pH. The lattice parameters of CdCl2 treated CdS were found to be a = 0.414 nm and c = 0.672 nm. Calculations based on the Sherrer formula showed significant grain growth after annealing with CdCl2. No apparent effect of ultrasonication on crystalline structure of CdS was seen in this method, although ultrasonication was noted to produce films with a higher quality optical surface. A maximum bath temperature was fixed at 70°C in order to suppress the rate of homogeneous reaction and minimise the evaporation of ammonia from the chemical bath.

Type
Research Article
Copyright
Copyright © Materials Research Society 2005

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References

1. Contreras, M.A., Egaas, B., Ramanathan, K., Hiltner, J., Swartzlander, A., Hasoon, F., Noufi, R., Prog. Photovoltaics:Res.Appl. 7 (1999) 331.Google Scholar
2. Catalano, A., Solar Energy Materilas and Solar Cells 41/42(1996)205.Google Scholar
3. Hall, R.B. and Meakin, J.D., Thin Solid Films, 63, 1979, p.203.Google Scholar
4. Sasikala, G., Thilakan, P., Subramanian, C., Solar Energy Materials & Solar Cells 62 (2000) 275.Google Scholar
5. Laukaitis, Giedrius, Lindroos, Seppo, Tamulevicius, Sigitas, Leskela, Markku, Applied Surface Science 185, (2001)134.Google Scholar
6. O'Brien, Paul, Saeed, Tahir, Journal of Crystal growth 158 (1996) 497.Google Scholar
7. Hasoon, F.S., Al-Jassim, M.M., Swartzelander, A., Sheidon, P., Al-Douri, A.A.J., and Alnajjar, A.A., 26th IEEE photovoltaic Specialists Conference, September 29- Octorber 3, 1997, Anaheim, California.Google Scholar
8. Chaure, N.B., Bordas, S., Samantilleke, A.P., Chaure, S.N., Haigh, J., Dharmadasa, I.M., Thin Solid Films 437 (2003) 10.Google Scholar
9. Chu, Ting L. and Chu, Shirley S., Solid-State Electronics 38 (1995) 533.Google Scholar
10. Choi, Jun Young, Kim, Kang-Jin, Yoo, Ji-Beom, Kim, Donghwan, Solar Energy 64 (1998) 41.Google Scholar
11. Cortes, A., Gomez, H., Marotti, R.E., Riveros, G., Dalchiele, E.A., Solar Energy Materials & Solar Cells 82 (2004) 21.Google Scholar
12. Ramaiah, K. S., Pilkington, R.D., Hill, A.E., Tomlinson, R.D., Bhatnagar, A.K., Materials Chemistry and Physics 68 (2001) 22.Google Scholar
13. Chu, T.L., Chu, S.S., Schultz, N., Wang, C., Wu, C.Q., J. Electrochem. Soc. 139 (1992) 2443.Google Scholar
14. Moutinho, H.R., Albin, D., Yan, Y., Dhere, R.G., Li, X., Perkins, C., Jiang, C.S., To, B., Al-Jassim, M.M., Thin Solid Films 436 (2003) 175.Google Scholar
15. Gibson, P.N., Ozsan, M.E., Lincot, D., Cowache, P., Summa, D., Thin Solid Films 361–362 (2000) 34.Google Scholar