光谱学与光谱分析 |
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Determination of Trace Elements in the Sediments of Poyang Lake Basin by Microwave-Assisted-ICP-AES |
GONG Xiao-feng1,2,CHEN Chun-li1,2,ZHAO Jin3,Barbara Zimmermann4,CUI Xiu-li1,ZHOU Wen-bin1* |
1. Key Laboratory of Poyang Lake Ecology and Bio-Resource Utilization of MOE,Nanchang University,Nanchang 330047,China 2. School of Environmental Science and Engineering of Nanchang University,Nanchang 330029,China 3. Nanchang Engineering and Research Institute of Nonferrous Metals,Nanchang 330002,China 4. Department of Chemistry of University Duisburg-Esseb,Germany |
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Abstract In order to investigate the seasonal,annual and alongshore variation of the trace elements in the sediments of Poyang Lake in recent years,ICP-AES was used to determine the sediment of each sampling site collected in the year of 2003 and 2005 in different seasons.The results indicated that the contents of the elements in the sediments of Poyang Lake were changing with seasons and years. Generally,the content of each element in low-water period was more higher than in high-water period. Compared with the year of 2003,the contents of Cu and Pb at Nan Ji-shan were lower in the year of 2005,while Cai Jia-wan was in the reverse situation. The content of Cu at Yao Gong-du was also lower in the year of 2005,but Pb was higher than in the year of 2003. To some extent,the contents of Cu,Pb,Cr and Zn were higher than the background value of Poyang Lake basin. Except Dawu River,the content of As at other sampling sites was within the background value. From Raohe River to the Raohe River’s entry in Poyang Lake,the content of each element trended to decrease gradually. By using microwave-assisted-ICP-AES to determine the trace elements in the sediments of Poyang Lake,it was proved to be a simple and fast,efficient method.
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Received: 2006-04-22
Accepted: 2007-02-28
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Corresponding Authors:
ZHOU Wen-bin
E-mail: xfgong@ncu.edu.cn
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Cite this article: |
GONG Xiao-feng,CHEN Chun-li,ZHAO Jin, et al. Determination of Trace Elements in the Sediments of Poyang Lake Basin by Microwave-Assisted-ICP-AES[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2007, 27(08): 1634-1637.
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URL: |
https://www.gpxygpfx.com/EN/Y2007/V27/I08/1634 |
[1] CHEN Jin-an,WAN Guo-jiang,HUANG Rong-gui(陈敬安,万国江,黄荣贵). Geology-Geochemistry(地质地球化学),1998,16(2): 1. [2] WEN Xiang-hua,DU Qing,LI Li-li,et al(文湘华,杜 青,李莉莉,等). Environmental Chemistry(环境化学),1996,15(2): 97. [3] FAN Cheng-xin,ZHU Yu-xin,JI Zhi-jun(范成新,朱育新,吉志军). Journal of Lake Sciences(湖泊科学),2002,14(3): 235. [4] Kuss H M. Fresenius J. Anal Chem.,1992,343: 788. [5] Binstock D A,Grohseetal P M. Asso. of Anal. Chem.,1991,7(2): 160. [6] XU Li-qiang,SHEN Wang-xing,ZHU Jin-fang(徐立强,沈王兴,朱锦方). Chinese Journal of Analytical Chemistry(分析化学),1990,18(7): 597. [7] HUANG Li-ben,ZENG Xuan-jin,SUN Ya-ru(黄立本,曾宪津,孙雅茹). Chinese Journal of Analytical Chemistry(分析化学),1984,12(7): 586. [8] SHI Ta-qing,LIANG Pei,LI Jing,et al(施踏青,梁 沛,李 静,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2005,25(3): 444. [9] GONG Xiao-feng,CHEN Chun-li,Barbara Zimmermann,et al(弓晓峰,陈春丽,Barbara Zimmermann,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2007,27(1): 155. [10] JIAN Min-fei,GONG Xiao-feng,YOU Hai,et al(简敏菲,弓晓峰,游 海,等). Resources and Environment in the Yangtze Basin(长江流域资源与环境),2004,13(6): 589. [11] JIAN Min-fei,YOU Hai,NI Cai-ying(简敏菲,游 海,倪才英). Journal of Lake Science(湖泊科学),2006,18(2): 127. |
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