光谱学与光谱分析 |
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Applications of Atomic Emission Spectrum from Liquid Electrode Discharge to Metal Ion Detection |
MAO Xiu-ling, WU Jian*, YING Yi-bin |
School of Biosystems Engineering and Food Science, Zhejiang University, Hangzhou 310029, China |
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Abstract The fast and precise detection of metal ion is an important research project concerning studies in diverse academic fields and different kinds of detecting technologies. In the present paper, the authors review the research on atomic emission spectrum based on liquid electrode discharge and its applications in the detection of metal ion. In the first part of this paper the principles and characteristics of the methods based on electrochemistry and spectroscopy were introduced. The methods of ion-selective electrode (ISE), anodic stripping voltammetry, atomic emission spectrum and atomic absorption spectrum were included in this part and discussed comparatively. Then the principles and characteristics of liquid electrode spectra for metal ion detection were introduced. The mechanism of the plasma production and the characteristics of the plasma spectrum as well as its advantages compared with other methods were discussed. Secondly, the authors divided the discharge system into two types and named them single liquid-electrode discharge and double-liquid electrode respectively, according to the number of the liquid electrode and the configuration of the discharge system, and the development as well as the present research status of each type was illustrated. Then the characteristics and configurations of the discharge systems including ECGD, SCGD, LS-APGD and capillary discharge were discussed in detail as examples of the two types. By taking advantage of the technology of atomic emission spectrum based on liquid electrode discharge, the detecting limit of heave metals such as copper, mercury and argent as well as active metal ions including sodium, potass and magnesium can achieve μg·L-1. Finally, the advantages and problems of the liquid-electrode discharge applied in detection of metal ion were discussed. And the applications of the atomic emission spectrum based on liquid electrode discharge were prospected.
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Received: 2009-02-05
Accepted: 2009-05-08
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Corresponding Authors:
WU Jian
E-mail: wujian69@zju.edu.cn
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