| 光谱学与光谱分析 |
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| Enhancement Effect of Laser-Processed Aqueous Solution on ICP Source Radiation |
| SU Hong-xin, XU Li-jing, CHEN Jin-zhong*, LI Xu, WEN Nuan |
| College of Physics Science and Technology, Hebei University, Baoding 071002, China |
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Abstract To enhance the intensity of inductively coupled plasma-atomic emission spectrum and improve the detection level of trace heavy metal elements, the surface tension and viscosity of the aqueous solution processed by near-infrared laser at wavelength of 976 nm were studied in the present paper. The influences of the treated solution on the spectral line intensity and signal-to-background ratio of the ICP source were observed. The results showed that when the laser irradiation time was 60min and the power density was 0.329 6 W·cm-2, the surface tension and viscosity of the solution decreased by 36.73% and 9.73% respectively compared to the untreated solution. Under the optimum conditions, the aqueous solution treated by the laser irradiation was introduced into the ICP source. By measuring the intensity of emission spectrum of the sample elements, the spectral line intensity of Cd, Cr, Cu, Hg, and Pb was enhanced by about 73.52%, 22.97%, 33.86%, 24.44% and 65.59% compared to the untreated solution, while the signal-to-background ratio increased by 76.03%, 21.74%, 32.17%, 22.68% and 65.32%, respectively. Spectral line intensity and signal-to-background ratio of the ICP source were significantly improved so that the foundation was established for reducing the analysis detection limits. Further more, the surface tension and viscosity of the processed aqueous solution remain the same within 30 minutes standing time with the stable physical properties. This simple and easy method of laser-processed aqueous solution helps improve the detection capabilities of ICP spectrometry.
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Received: 2013-07-22
Accepted: 2013-11-21
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Corresponding Authors:
CHEN Jin-zhong
E-mail: chenjinzhongcn@126.com;lijingxuhbu@163.com
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