Symple synthesis of lead(II) oxide nanostructures based on spontaneous solution-solution transfer of NH3 gas

Mansournia, Mohammadreza; Hajiebrahimi, Azimeh; Moradinia, Elham

doi:10.22075/chem.2017.2670.

Symple synthesis of lead(II) oxide nanostructures based on spontaneous solution-solution transfer of NH3 gas

Document Type : Original Article

Authors

10.22075/chem.2017.2670.

Abstract

In this study, lead(II) oxide nanostructures were prepared using lead(II) acetate trihydrate and urea as the precursors in the alkaline condition derived from an ammonia atmosphere, and at two temperatures, ambient and 70 °C. Moreover, the effect of urea on the structure, size and shape of the as-synthesized nanostructures was investigated. Further, X-ray diffraction (XRD) and Furrier transformation infra red spectroscopy (FT-IR) techniques were used in order to characterize the as-obtained nanostructures, and the scanning electron microscopy (SEM) images were applied for their size and morphological study.

Keywords

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Symple synthesis of lead(II) oxide nanostructures based on spontaneous solution-solution transfer of NH3 gas

References

[1] L. Li, X. Zhua, D. Yang, L. Gao, J. Liu, R. Vasant Kumar, J. Yang, Hazardous Materials, 203– 204 (2012) 274.

[2] H.J. Terpstra, R.A. de Groot, C. Haas, Physical Review B, 52 (1995) 11690.

[3] R.C. Keezer, D.L. Bowman, J.H. Becker, Journal of Applied Physics, 39 (1968) 2062.

[12] K.N. Wong, P.S. Khiew, D. Isa, W.S. Chiu, Materials Letters, 128 (2014) 97.

[13] H. Sadeghzadeh, A. Morsali, Ultrasonics Sonochemistry, 18 (2011) 80.

[35] F. Behnoudnia, H. Dehghani, Inorganic Chemistry, 24 (2012) 32.

[36] M. S. Refat, S. M. Teleb, S. A. Sadeek, Spectrochimica Acta Part A, 60 (2004) 2803.

Volume 12, Issue 42
March 2017
Pages 157-166

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Symple synthesis of lead(II) oxide nanostructures based on spontaneous solution-solution transfer of NH3 gas

References

[1] L. Li, X. Zhua, D. Yang, L. Gao, J. Liu, R. Vasant Kumar, J. Yang, Hazardous Materials, 203– 204 (2012) 274.

[2] H.J. Terpstra, R.A. de Groot, C. Haas, Physical Review B, 52 (1995) 11690.

[3] R.C. Keezer, D.L. Bowman, J.H. Becker, Journal of Applied Physics, 39 (1968) 2062.

[12] K.N. Wong, P.S. Khiew, D. Isa, W.S. Chiu, Materials Letters, 128 (2014) 97.

[13] H. Sadeghzadeh, A. Morsali, Ultrasonics Sonochemistry, 18 (2011) 80.

[35] F. Behnoudnia, H. Dehghani, Inorganic Chemistry, 24 (2012) 32.

[36] M. S. Refat, S. M. Teleb, S. A. Sadeek, Spectrochimica Acta Part A, 60 (2004) 2803.

Volume 12, Issue 42March 2017Pages 157-166

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Volume 12, Issue 42
March 2017
Pages 157-166