| 光谱学与光谱分析 |
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| Ultra-Fine Pressed Powder Pellet Sample Preparation XRF Determination of Multi-Elements and Carbon Dioxide in Carbonate |
| LI Xiao-li, AN Shu-qing, XU Tie-min, LIU Yi-bo, ZHANG Li-juan, ZENG Jiang-ping,WANG Na |
| Tianjin Geological Survery Center, Tianjin 300170,China |
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Abstract The main analysis error of pressed powder pellet of carbonate comes from particle-size effect and mineral effect. So in the article in order to eliminate the particle-size effect, the ultrafine pressed powder pellet sample preparation is used to the determination of multi-elements and carbon-dioxide in carbonate. To prepare the ultrafine powder the FRITSCH planetary Micro Mill machine and tungsten carbide media is utilized.To conquer the conglomeration during the process of grinding, the wet grinding is preferred. The surface morphology of the pellet is more smooth and neat, the Compton scatter effect is reduced with the decrease in particle size. The intensity of the spectral line is varied with the change of the particle size, generally the intensity of the spectral line is increased with the decrease in the particle size. But when the particle size of more than one component of the material is decreased, the intensity of the spectral line may increase for S, Si, Mg, or decrease for Ca,Al,Ti,K, which depend on the respective mass absorption coefficient . The change of the composition of the phase with milling is also researched. The incident depth of respective element is given from theoretical calculation. When the sample is grounded to the particle size of less than the penetration depth of all the analyte, the effect of the particle size on the intensity of the spectral line is much reduced. In the experiment, when grounded the sample to less than 8μm(d95), the particle-size effect is much eliminated, with the correction method of theoretical αcoefficient and the empirical coefficient , 14 major, minor and trace element in the carbonate can be determined accurately. And the precision of the method is much improved with RSD<2%, except Na2O. Carbon is ultra-light element, the fluorescence yield is low and the interference is serious. With the manual multi-layer crystal PX4, coarse collimator, empirical correction, X-ray spectrometer can be used to determine the carbon dioxide in the carbonate quantitatively. The intensity of the carbon is increase with the times of the measurement and the time delay even the pellet is stored in the dessicator. So employing the latest pressed powder pellet is suggested.
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Received: 2014-04-24
Accepted: 2014-07-18
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Corresponding Authors:
LI Xiao-li
E-mail: zanghonghua97@qq.com
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[1] LIU Kai, WANG Ming-hui, MA Qiao-yu(刘 凯,王明慧,马巧玉). Metallurgical Analysis(冶金分析), 2003, 23(6): 56.
[2] LI Chao(李 超). Shandong Metallurgy(山东冶金), 2006, 28(6): 77.
[3] DU Mi-fen, ZHANG Fen-lou, YANG Qi-feng, et al(杜米芬,张芬楼,杨旗风,等). Chinese Journal of Spectroscopy Laboratory(光谱实验室), 2001, 18(5): 62.
[4] LIU Jiang-bin, CAO Cheng-dong, ZHAO Feng, et al(刘江斌,曹成东,赵 峰,等). Rock and Mineral Analysis(岩矿测试), 2008, 27(2): 149.
[5] WANG Xiao-wen(汪晓文). Analytical Instrument(分析仪器), 2004, 26(4): 29.
[6] YUAN Xiu-ru, YU Yu, ZHAO Feng, et al(袁秀茹, 余 宇,赵 峰,等). Rock and Mineral Analysis(岩矿测试), 2009, (4): 376.
[7] LI Guo-hui, FAN Shou-zhong, CAO Qun-xian, et al(李国会, 樊守忠, 曹群仙, 等). Rock and Mineral Analysis(岩矿测试), 1997, 16(1): 45.
[8] LIU Jian-kun, ZHENG Rong-hua(刘建坤,郑荣华). Modern Scientific Instrument(现代科学仪器), 2009, 6: 32.
[9] Marek Lankosz. X-Ray Spectrometry, 1988, 17(2): 161.
[10] Barbara Holynska, Andrzej Markowicz. X-Ray Spectrometry, 1982, 11(3): 117. |
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