铅锌矿冶区水稻土氟污染状况及污染源分析
Fluorine Pollution and Pollution Sources of the Paddy Soils in a Lead-Zinc Mining Area
DOI: 10.12677/AEP.2015.52003, PDF, HTML, XML, 下载: 2,506  浏览: 8,609  国家科技经费支持
作者: 邬 卉, 吴 川, 吴雪娥, 黄 玲, 薛生国:中南大学冶金与环境学院,湖南 长沙
关键词: 氟污染水稻土矿区土壤健康指数地氟病Fluorine Pollution Paddy Soil Mining Area Soil Health Index Endemic Fluorosis
摘要: 以华南某铅锌矿冶区周边农田为研究对象,利用网格布点法,系统调查研究区域水稻土氟污染状况,开展铅锌矿冶区周边农田土壤氟污染源分析。结果表明,水稻田土壤氟污染严重,73%的采样点土壤氟含量超过800 mg∙kg−1,土壤氟含量平均值高达1118 mg∙kg−1;土壤健康指数平均值为1.36,绝大部分采样区域处于土壤高氟污染区,易诱发地氟病;土壤pH值、铅锌含量与水稻土氟的分布存在相关关系,土壤氟含量与土壤pH值呈正相关,与土壤铅含量呈负相关;萤石矿开采和伴生萤石矿的开采是水稻土氟污染的主要来源。研究结果将为掌握当地土壤氟污染状况、预防地氟病发生、改善水稻田土壤环境提供科学依据。
Abstract: Fluorine pollution of a certain lead-zinc mining area and pollution sources of surrounding farmlands were investigated using mesh points method. The results showed that the fluorine pollution of the paddy soils was serious, with 73% of sampling areas higher than 800 mg∙kg−1, which would easily lead to endemic fluorosis. Average soil fluorine content was 1118 mg∙kg−1, and the average soil health index of fluorine was 1.36, and average soil pH was 5.40. Soil lead contents were ranged from 43 mg∙kg−1 to 4961 mg∙kg−1, with an average of 517 mg∙kg−1. Soil zinc contents were ranged from 83 mg∙kg−1 to 4620 mg∙kg−1, with an average of 650 mg∙kg−1. Moreover, fluorine contents were significantly positively correlated with pH (P < 0.05), and negatively correlated with lead contents. Fluorite mining, mineral mine mining and smelting may be the main sources of fluorine pollution in paddy soils of the investigated area. Soil parent material, pesticides and chemical fertilizers could cause fluorine contamination in the paddy soils. The research is potential for improving soil environments and the control of endemic fluorosis.
文章引用:邬卉, 吴川, 吴雪娥, 黄玲, 薛生国. 铅锌矿冶区水稻土氟污染状况及污染源分析[J]. 环境保护前沿, 2015, 5(2): 15-21. http://dx.doi.org/10.12677/AEP.2015.52003

参考文献

[1] Cao, J.L., Chen, J.J., Wang, J.D., Jia, R.H., Xue, W.J., Luo, Y.J. and Gan, X. (2013) Effects of fluoride on liver apop-tosis and Bcl-2, Bax protein expression in freshwater teleost, Cyprinus carpio. Chemosphere, 91, 1203-1212.
[2] 李静, 谢正苗, 徐建明, 吴卫红 (2005) 我国氟的土壤健康质量指标及评价方法的初步探讨. 浙江大学学报(农业与生命科学版), 31, 593-597.
[3] 陈高武, 唐将, 杨德生 (2007) 三峡库区地方性氟中毒病区与非病区土壤地化学. 长江流域资源与环境, 16, 379-383.
[4] 张永航 (2007) 贵州省地氟病区土壤中氟的形态分布特征. 贵州师范大学学报(自然科学版), 25, 41-47.
[5] 罗宏, 杨志峰 (2000) 湖北氟中毒流行的环境地理分析. 北京师范大学学报(自然科学版), 36, 122-126.
[6] 李达圣, 安冬, 何平 (2005) 贵州省燃煤型地方性氟中毒流行现状调查分析. 中国地方病学杂志, 24, 651-654.
[7] Yuan, Y.N., Chai, L.Y., Yang, Z.H., Liao, Y.P., Deng, X.H. and Zhang, S.J. (2013) Application of polymeric aluminum salts in remediation of soil contaminated by Pb, Cd, Cu, and Zn. Journal of Central South University, 20, 1638- 1644.
[8] 郭朝晖, 王凤永, 宋杰, 肖细元, 苗旭峰 (2011) 污染土壤–芦竹–水体系中As, Cd, Pb 和Zn 的渗漏与迁移特征. 中南大学学报(自然科学版), 42, 2184-2192.
[9] 杨英, 赵彦琦, 田采霞 (2013) 铝厂附近农田土壤氟污染现状及防治措施研究. 环境科学与管理, 38, 75-78.
[10] 郭朝晖, 宋杰, 肖细元, 黄虹, 苗旭峰 (2009) 有色矿冶区污染蔬菜土壤中重金属活性. 中南大学学报(自然科学版), 40, 12-18.
[11] 郑文武, 田亚平, 邹君, 邓运员, 刘晓燕, 邓美容 (2010) 基于GIS的南方丘陵生态脆弱区土地利用适宜性研究——以衡阳盆地为例. 地理与地理信息科学, 26, 79-83.
[12] 谢正苗, 李静, 徐建明, 吴卫红 (2006) 基于GIS杭嘉湖平原土壤氟的质量评价. 环境科学, 27, 1026-1030.
[13] An, J., Lee, H.A., Lee, J. and Yoon, H.O. (2015) Fluorine distribution in soil in the vicinity of an accidental spillage of hydrofluoric acid in Korea. Chemosphere, 119, 577-582.
[14] Msonda, K.W.M., Masamba, W.R.L. and Fabiano, E. (2007) A study of fluoride groundwater oc-currence in Nathenje, Lilongwe, Malawi. Physics and Chemistry of the Earth, 32, 1178-1184.
[15] 刘昌福 (2007) 湖南双江口萤石矿矿床特征、控矿因素及找矿标志. 中国矿业, 16, 96-98.
[16] 刘铁庚, 叶霖, 李乙雨, 曾明果 (2002) 银矿与萤石的时空关系. 矿物学报, 22, 169-174.
[17] 王振亮, 鲁瑞君, 林天亮, 吴新刚 (2013) 浅析中国萤石矿分布特征及其成矿规律. 中国非金属矿工业导刊, 5, 56-59.
[18] Amit, B., Eva, K. and Mika, S. (2011) Fluoride removal from water by adsorption—A review. Chemical Engineering Journal, 171, 811-840.
[19] 农业环境背景值研究编写组 (1997) 农业环境背景值研究. 上海科学技术出版社, 上海.
[20] 李随民, 栾文楼, 韩腾飞, 宋泽峰, 崔刑涛 (2012) 冀中南平原区土壤氟元素来源分析.中国地质, 39, 794-803.
[21] Wang, P., Wang, T.Y., Giesy, J.P. and Lu, Y.L. (2013) Perfluorinated compounds in soils from Liaodong Bay with concentrated fluorine in-dustry parks in China. Chemosphere, 91, 751-757.
[22] 吴卫红, 谢正苗, 徐建明, 李静, 陈建军 (2006) 杭嘉湖地区水稻土中氟的分布特征. 土壤学报, 43, 898-903.
[23] Sinha, S., Saxena, R. and Singh, S. (2000) Fluoride removal from water by Hydrilla verticillata (l.f.) royle and its toxic effects. Bulletin of Environmental Contamination and Toxicology, 65, 683-690.