Quality Assessment of Sand as Silicon Dioxide Collected from the Sudanese Areas (Bara, Elmtama and Karema) for Glass Industry
Science Journal of Chemistry
Volume 5, Issue 5, October 2017, Pages: 71-75
Received: Jul. 28, 2017;
Accepted: Sep. 11, 2017;
Published: Nov. 17, 2017
Views 2449 Downloads 86
Mohamed Alzuabir Almaleeh, Department of Chemistry, Faculty of Science and Technology, Omdurman Islamic University, Khartoum, Sudan
Mohamed Ezeldin, Department of Chemistry, Faculty of Science and Technology, Omdurman Islamic University, Khartoum, Sudan
Said Milad, Faculty of Veterinary Medicine, Zaytouna University, Tarhona, Libya
The silicon dioxide and microcline, samples were collected from the North Kordofan state Bara area, River Nile state Elmatama area and Karema. Then samples were subjected to X-ray diffractometer "XRD" accodrding to standard testMethods. Elemnts compostion was charactrized for all samples by X-ray florescence spectrometer "XRF". The particles size was carried out using sieve standards. Samples were acidified to improve the quality of silica. Silicon dioxide of Bara sand was found to be 100%, while that of Elmtama was 96.6% silicon dioxide and 3.4% microcline sandand for Karima sand 94% silicon dioxide and 6% microcline. The percentages of the silica sand were found to be 95.8% for Bara, 90.9% for Elmtama and 84.2% for karema. The iron oxide percentage for Bara was found 0.03%. The particle size for Bara, Karema and Elmtama were found to be (60, 100, 140mm), respectively.
Mohamed Alzuabir Almaleeh,
Quality Assessment of Sand as Silicon Dioxide Collected from the Sudanese Areas (Bara, Elmtama and Karema) for Glass Industry, Science Journal of Chemistry.
Vol. 5, No. 5,
2017, pp. 71-75.
Copyright © 2017 Authors retain the copyright of this article.
This article is an open access article distributed under the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/
) which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
A. F. B. Braga, S. P. Moreira, P. R. Zampieri, J. M. G. Bacchin, P. R. Mei, Solar Energy Materials and Solar Cells 92, Issue 4, 418–424 (2008) 00014-p. 3
S. Pizzini Solar Energy Materials and Solar Cells 94, Issue 9, 1528-1533 (2010)
V. Raman, K. Parashar and S. R. Dhakate, Journal of Sol-Gel Science and Technology 25, 175 (2002)
A. A. Popovich, P. A. Nikiforov, D. V. Onishchenko, A. K. Tsvetnikov, and V. G. Kuryavyi, Theoretical Foundations of Chemical Engineering, 42, number 5, 603-605 (2008)
B. N. Mukashev, Kh. A. Abdullin, M. F. Tamendarov, T. S. Turmagambetov, B. A. Beketov, M. R. Page, D. M. Kline, Solar Energy Materials & Solar Cells 93 1785 (2009)
J. C. S. Pires, J. Otubo, A. F. B. Braga, P. R. Meia, Journal of Materials Processing Technology 169 16 (2005)
C. Alemany, C. Trassy, B. Pateyron, K. -I. Li, Y. Delannoy, Solar Energy Materials & Solar Cells 72 41 (2002)
G. Flamant, V. Kurtcuoglu, J. Murray, A. Steinfeld, Solar Energy Materials and Solar Cells, 90 2099 (2006)
T. Shimpo, T. Yoshikawa, K. Morita, Metallurgical and Materials Transactions B 35 277 (2004)
Mohamed Ezeldin, Sulieman A. G. Nasir, Ali M. Masaad, Nawal M. Suleman. Determination of Some Heavy Metals in Raw Petroleum Wastewater Samples Before and After Passing on Australis Phragmites Plant. American Journal of Environmental Protection. Vol. 4, No. 6, 2015, pp. 354-357. doi: 10.11648/j.ajep.20150406.22.
A. D. Farmer, A. F. Collings, G. J. Jameson, Ultrasonics Sonochemistry 7 243 (2000)
D. A. Barrett, V. A. Brown, R. C. WAston, M. C. Davues, P. N. Shaw, H. J. Ritchie, Journal of Chromatoghraphy A, 905 69 (2001)
K. Y. Lee, Y. Y. Yoon, S. B. Jeong, Y. B. Chae, K. S. Ko, J. Radioanal Nucl. Chen 282 629 (2009)
D. Mowla, G. Karimi, K. Ostadnezhad, separation and purification Technology 58419 (2008).