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洞庭湖“四水”入湖河床沉积物重金属污染特征
Heavy metal contamination in bed sediments from the four inlets of Xiangjiang, Zijiang, Yuanjiang, and Lishui rivers to Dongting Lake, China

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方小红 1,2   彭渤 1,2 *   宋照亮 3   谭长银 1,2   万大娟 1,2   王欣 1,2   颜川云 1,2   谢依婷 1,2   涂湘林 4  
文摘 对洞庭湖湘、资、沅、澧“四水"入湖河床沉积物进行了沉积柱芯钻探取样,利用等离子质谱仪(ICP-MS)对沉积物重金属等微量元素进行了地球化学分析。结果表明,“四水”入湖河床沉积物中,重金属Bi、Cd、Cr、Mn、Cu、Zn、Pb和Tl等含量变化大,分布极不均匀,而Ba、Sc、Th、U、Cs、Ga、Ge、Rb、Zr、Hf和Nb等微量元素及稀土元素含量变化小,分布相对均匀。微量元素富集系数(f_(E,C)、f_(E,D)值)和主成分分析结果表明,沉积物中显著富集(f_(E,C)> 1.5,f_(E,D)> 1.5)的重金属Bi、Cd、Cr、Mn、Ni、Cu、Zn、Pb和Tl等既有自然源的带入,又有人为源的贡献;而Ba、Cs、Sc、Th、U、Ga、Ge、Rb、Nb、Ta、Mo、Sr、Zr、Hf和REE+ Y等无明显富集特征的微量元素为自然源。地累积指数评价结果显示,湘、资、沅、澧“四水”入湖沉积物依次存在Cd-Bi-Pb-Zn-Mn-Cu-Tl、Cd-Bi、Cd和Cd-Mn-Cu-Ni-Cr等元素组合的重金属污染。且以湘江入湖沉积物重金属污染的元素种类最多、污染程度最强,澧水次之,沅江沉积物重金属污染的元素种类最少、污染程度最弱。结合洞庭湖沉积物重金属污染空间变化特征的对比分析,本研究得到结论:湘江为洞庭湖沉积物重金属污染带入了Cd、Pb、Zn、Cu、Hg、As、Bi、Cr和Ni等重金属;资江带入了Cd、Pb、Zn、Hg、As和Bi等重金属;沅江带入了Cd和Hg等重金属;澧水带入了Cd、Pb、Cu、Hg、Cr和Ni等重金属。洞庭湖重金属污染治理应密切关注重金属Cd的污染,空间上应特别重视湘江和澧水引起的重金属污染。
其他语种文摘 This paper reports the results of a study on heavy metal contamination developed in bed sediments from the four inlets of the Xiangjiang, Zijiang, Yuanjiang, and Lishui rivers to Dongting Lake, China. Sediment samples were collected by drilling in the four river channels, and the concentrations of heavy metals and other trace elements in the sediments were analyzed using inductively coupled plasma mass spectrometry (ICP-MS). The results show that the concentrations of the heavy metals Bi, Cd, Cr, Mn, Cu, Zn, Pb and T1 vary significantly. This may suggest that these heavy metals are heterogeneously distributed in sediments of the four river inlets. However, the concentrations of trace elements Ba, Sc, Th, U,Cs, Ga, Ge, Rb, Zr, Hf, Nb, and rare earth elements (REE) are significantly less variable, possibly indicating that these trace elements are relatively homogeneously distributed in the sediments. The enrichment factor calculations (f_(E,C)f_(E,D) value) and the principal component analysis (PCA) on Al-normalized concentrations of heavy metals and others trace elements show that the heavy metals Bi, Cd, Cr, Mn, Ni, Cu, Zn, Pb and Tl are significantly enriched in the sediments, and these metals are believed to be contributed from both natural processes (rock weathering) and anthropogenic activities (mining, metal refining). The trace elements Ba, Cs, Sc, Th, U, Ga, Ge, Rb, Nb, Ta, Mo, Sr, Zr, Hf, Y, and REE are less significantly enriched in the sediment, and these trace elements may be contributed mostly from the natural processes occurring in the watershed. The assessment of heavy metal contamination using the geo-accumulation index (I_(geo)) suggests that the inlet sediments of the Xiangjiang, Zijiang, Yuanjiang, and Lishui rivers are contaminated by heavy metals as Cd-Bi-Pb-Zn-Mn-Cu-Tl, Cd-Bi, Cd, and Cd-Mn-Cu-Ni-Cr assemblages, respectively. The inlet sediments of the Xiangjiang and Lishui rivers are most seriously contaminated by a suite of heavy metals, while those of the Zijiang and Yuanjiang rivers are slightly contaminated by heavy metal Cd and Bi. In accordance with the spatial variation of heavy metal contamination developed in the Dongting lake sediments, the present study suggests that the Xiangjiang River has contributed to the heavy metal contamination of the Dongting lake with the heavy metals Cd, Pb, Zn, Cu, Hg, As, Bi, Cr and Ni; the Zijiang River by with the heavy metals Cd, Pb, Zn, Hg, As and Bi, the Yuanjiang River by with the heavy metals Cd and Hg, and the Lishui River by with heavy metals Cd, Pb, Cu, Hg, Cr and Ni. Therefore, the strategy for protecting the lake watershed should pay a great attention to the contamination caused by heavy metal Cd in the inlet sediments of the four rivers, and to the heavy metal contamination developed in sediments of the Xiangjiang and Lishui river inlets to the lake.
来源 地球化学 ,2019,48(4):378-394 【核心库】
DOI 10.19700/j.0379-1726.2019.04.006
关键词 重金属污染 ; 微量元素 ; 人为源 ; 自然源 ; 入湖河床沉积物 ; 洞庭湖
地址

1. 湖南师范大学资源与环境科学学院, 湖南, 长沙, 410081  

2. 湖南师范大学, 湖南省环境重金属污染机理与生态修复实验室, 湖南, 长沙, 410081  

3. 天津大学表层地球系统科学研究院, 天津, 300072  

4. 中国科学院广州地球化学研究所, 同位素地球化学国家重点实验室, 广东, 广州, 510640

语种 中文
文献类型 研究性论文
ISSN 0379-1726
学科 地质学;环境污染及其防治
基金 湖南省地理学一流学科建设项目 ;  湖南省高校科技创新团队支持计划项目(2014) ;  国家自然科学基金 ;  湖南省研究生科研创新项目
文献收藏号 CSCD:6576116

参考文献 共 47 共3页

1.  Fok L. The influence of geology and land use on the geochemical baselines of the East River basin, China. Catena,2013,101:212-225 CSCD被引 3    
2.  Machado A A S. Metal fate and effects in estuaries: A review and conceptual model for better understanding of toxicity. Sci Total Environ,2016,541:268-281 CSCD被引 12    
3.  Peng B. Geochemistry of trace metals and Pb isotopes of sediments from the lowermost Xiangjiang River, Hunan Province (P. R. China): Implications on sources of trace metals. Environ Earth Sci,2011,64(5):1455-1473 CSCD被引 20    
4.  Li F. Spatial risk assessment and sources identification of heavy metals in surface sediments from the Dongting Lake, Middle China. J Geochem Explor,2013,132:75-83 CSCD被引 53    
5.  方小红. 沅江入湖河床沉积物重金属污染演化地球化学分析. 环境科学学报,2018,38(7):2586-2598 CSCD被引 9    
6.  方小红. 沅江下游入湖段河床沉积物重金属污染特征. 地理研究,2016,35(10):1887-1898 CSCD被引 8    
7.  Singh P. Major, trace and REE geochemistry of the Ganga River sediments: Influence of provenance and sedimentary processes. Chem Geol,2009,266:242-255 CSCD被引 30    
8.  Du Y. Interpretation of the environmental change of Dongting Lake, middle reach of Yangtze River, China, by ~(210)Pb measurement and satellite image analysis. Geomorphology,2001,41:171-181 CSCD被引 32    
9.  Forstner U. Traceability of sediment analysis. Trac Trend Anal Chem,2004,23:217-236 CSCD被引 5    
10.  Qian Y. Heavy metal contamination and its environmental risk assessment in surface sediments from Lake Dongting, People's Republic of China. Bull Environ Contam Toxicol,2005,75(1):204-210 CSCD被引 15    
11.  Tylmann W. Heavy metals in sediments as evidence for recent pollution and quasi-estuarine processes: An example from Lake Druzno, Poland. Environ Geol,2007,53(1):35-46 CSCD被引 2    
12.  Hansen A M. Lake sediment cores as indicators of hostorical metal(loid) accumulation-A case study in Mexico. Appl Geochem,2012,27:1745-1752 CSCD被引 7    
13.  Bertand S. Geochemistry of surface sediments from the fjords of Northern Chilean Patagonia (44-47°S): Spatial variability and implications for paleoclimate reconstructions. Geochim Cosmochim Acta,2012,76:125-146 CSCD被引 3    
14.  Garon M. Silver and lead in high-altitude lake sediments: Proxies for climate changes and human activities. Appl Geochem,2012,27:760-773 CSCD被引 1    
15.  童霆. 河口三角洲元素含量与矿产资源--以湘资沅澧为例. 第四纪研究,2005,25(3):298-305 CSCD被引 18    
16.  祝云龙. 洞庭湖沉积物中重金属污染特征与评价. 湖泊科学,2008,20(4):477-485 CSCD被引 59    
17.  祝云龙. 大通湖及东洞庭湖区生物体重金属的水平及其生态评价. 湖泊科学,2007,19(6):690-697 CSCD被引 11    
18.  姚志刚. 洞庭湖沉积物重金属环境地球化学. 地球化学,2006,35(6):629-638 CSCD被引 60    
19.  申锐莉. 洞庭湖湖区水质时空演化(1983-2004年). 湖泊科学,2007,19(6):677-682 CSCD被引 21    
20.  Zhong L Y. Characterization of heavy metal pollution in the paddy soils of Xiangyin County, Dongting lake drainage basin, central south China. Environ Earth Sci,2012,67(8):2261-2268 CSCD被引 10    
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