D. C. Electrical Conductivity of Ga doped ZnO

N. R. Thakare; V. R. Chinchamalatpure

doi:10.32628/IJSRST52310526

Authors

N. R. Thakare Department of Physics. P R. Pote Engineering. College Amravati, India
V. R. Chinchamalatpure Department of Physics Hutatma Rashtriya Arts and Science College, Ashti, Distt: Wardha, India

DOI:

https://doi.org/10.32628/IJSRST52310526

Keywords:

D.C. Electrical Conductivity, ZnO

Abstract

Doped ZnO is seen as a potential substitute to the expensive Sn doped material, as a transparent electrode in optoelectronic devices. Here, highly conductive and transparent Ga doped ZnO were prepared by chemical vapor deposition. The lowest resistivity and highest carrier concentration ever reported for CVD grown ZnO, Ga was achieved due to using oxygen poor growth conditions enabled by diethylzinc and triethylgallium precursors. Physical properties like Electrical Conductivity of Zinc Oxide (ZnO) are studied with different doping in it. The dopant to study the varying physical properties of the ZnO semiconductor with respect to Gallium (Ga) semiconductor with changing doping by weight percent of0, 1, 3 and 5 wt. % gallium doped ZnO system are reported here. The electrical properties include dc electrical studies.

References

Seiyama T., Kato A., Fujiishi K., Nagatani M., Anal. Chem., 34(1962), 1502.
Moseley P. T., Sens Actuators B Chem., 6(1992), 149.
Seiyama T., Era F., Zairyo-Kagaku Jpn., 8(1971), 232.
Pizzini S., Butta N., Narducci D., Palladino M., J. Electrochem. Soc., 136(1989), 1945.
Wagh M. S., Jain G. H., Patil D. R., Patil S. A., Patil L. A., Sens. Actuators B, Chem. , 115(2006), 128.
Patil L.A., Patil D.R., Sens Actuators B Chem., 120 (2006), 316.
Patil D.R., Patil L.A., Sensors and Transducers, 70(2006), 661.
Wang Yan, Kong Fanhong, Zhu Baolin, Wang Shurong, Wu Shihua, Huang Weiping, Mater. Sci. Eng. B, 140(2007), 98.
Neri G., Bonavita A., Rizzo G., Galvagno S., Pinna N., Niederberger M., Capone S., Siciliano P., Sens Actuators B Chem., 122(2007), 564.
Kapse V.D., Ghosh S.A., Chaudhari G.N., Raghuwanshi F.C., Talanta, 76(2008), 610.
Hotovy I., Rehacek V., Sicilian P., Capone S., Spiess L., Thin Solid Films, 418(2002), 9.
Liu R., Vertegel A.A., Bohannan E.W., Sorenson T.A. And Switzer J.A., Chem. Mater., 13(2001), 508.
Kaur R., Singh A.V., Sehrawat K., Mehra N.C. And Mehra R.M., J. Non-Crystal. Solids, 352(2001), 2565.
Kubota J., Haga K., Kashiwaba Y., Watanabe H., Zhang B.P. And Segawa Y., Appl. Surf. Sci., 216(2003), 431.
Singh S., Thiyagarajan P., Kant K.M., Anita D., Thirupathiah S., Rama N., Tiwari B., Kottaisamy M. And Rao M.S.R., J. Phys. D: Appl. Phys., 40(2007), 6312.
Reynolds D.C., Look D.C. And Jogai B., Appl. Phys., 89(2001), 6189.
Kim K.H., Park K.C., Ma D.Y., J. Appl. Phys., 81(1997), 7764.
Jimenez-Gonzalez A.E., J. Solid State Chem.,128(1997), 176.
Nanto, H.; Minami, T.; Takata, S. J. Appl. Phys., 60(1986), 482.
Kapse V.D., Ghosh S.A., Chaudhari, G.N., Raghuwanshi F.C., Vacuum, 83(2009), 346.
Baruwati B., Kishore Kumar D., Manorama S.V., Sens Actuators B, Chem., 119(2006),676.
Kwon Y.J., Kim K.H., Lim C.S., Shim K.B., J. Ceram. Proc. Res., 3(2002), 146.
Silva R.F., Zaniquelli M.E.D., Colloid Surface. A, 198–200(2002), 551.
Li H., Wang J., Liu H., Yang C., Xu H., Li, X. Cui H., Vacuum, 77(2004), 57.
Dong L.F., Cui Z.L., Zhang Z.K., Nanostructure. Mater., 8 (7) (1997), 815.
Sze S.M., Chemical Sensors, Wiley, New York, 1995, Pp. 383.
Watson J., Sens Actuators B Chem., 5(1984), 29.
Morrison S.R., Sens Actuators B Chem., 12(1987), 425.
Korotcenkov G., Boris I., Cornet A., Rodriguez J., Cirera A., Golovanov V., Lychkovsky Yu., Karkotsky G., Sens Actuators B Chem., 120(2007), 657.

D. C. Electrical Conductivity of Ga doped ZnO

Authors

DOI:

Keywords:

Abstract

References

Downloads

Published

Issue

Section

License

How to Cite