光谱学与光谱分析 |
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Determination of Trace Copper and Zinc in Vegetable Oils by Derivative Flame Atomic Absorption Spectrometry Combined with Flow-Injection Technique |
CHEN Lan-ju1,ZHENG Lian-yi1,ZHAO Di-shun1,SUN Han-wen2 |
1. Hebei University of Science and Technology,Shijiazhuang 050018,China 2. Department of Chemistry, Hebei University,Baoding 071002,China |
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Abstract A new method was proposed to determine trace copper and zinc in vegetable oils by derivative flame atomic absorption spectrometry combined with flow-injection technique. The flaw that sampling is large and matrix interference was serious in conventional Flame Atomic Absorption Spectrometry(FAAS) was overcome by flow-injection sampling technique. The sensitivity and signal selectivity were enhanced when derivative technique was used in flame atomic absorption spectrometry. The results of determinations of copper and zinc in vegetable oils were satisfactory by derivative flame atomic absorption spectrometry combined with flow-injection,which were not done by conventional FAAS or flow-injection FAAS. The sensitivities were 0.004 0 and 0.001 2 μg·mL-1 for copper and zinc,respectively,and the relative standard deviation was 1.1%-5.1%.
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Received: 2002-10-28
Accepted: 2003-01-16
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Corresponding Authors:
CHEN Lan-ju
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Cite this article: |
CHEN Lan-ju,ZHENG Lian-yi,ZHAO Di-shun, et al. Determination of Trace Copper and Zinc in Vegetable Oils by Derivative Flame Atomic Absorption Spectrometry Combined with Flow-Injection Technique [J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2004, 24(08): 1013-1015.
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URL: |
http://www.gpxygpfx.com/EN/Y2004/V24/I08/1013 |
[1] Zalts A et al. An. Asoc. Quim. Agent,1986,74(1):50. [2] Hon P K et al. Analytica Chimica Acta,1980,113:175. [3] Hoequeuet P. Atomic Spectrosc.,1985,6(3):69. [4] Sun H J. Am. Oil Chem. Soc.,1989,66(4):549. [5] TAO Rui,PENG Xi-yu(陶 锐,彭喜雨). Chinese J. of Spectroscopy Laboratory(光谱实验室),1993,10(1):1. [6] CHEN Shu-yu,LIN Shu-xin(陈树榆,林淑欣). Chinese J. of Anal. Chem.(分析化学),1988,16(5):460. [7] Calapa J R et al. Atomic Spectrosc.,1988,9(4):107. [8] Mason T J et al. Pure Applied Chemistry, 1988, 60: 893.
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