华北平原饮用地下水碘分布及碘盐分区供应探讨

生态与农村环境学报 ›› 2014, Vol. 30 ›› Issue (1): 9-14.doi:

华北平原饮用地下水碘分布及碘盐分区供应探讨

钱永, 张兆吉, 费宇红, 陈京生, 李亚松

中国地质科学院水文地质环境地质研究所

收稿日期:2013-05-17 修回日期:2014-01-03 出版日期:2014-01-25 发布日期:2014-02-14
通讯作者: 陈京生中国地质科学院水文地质环境地质研究所 E-mail:cjs1957@sina.com
作者简介:钱永（1982-），男，河南信阳人，助理研究员，博士生，主要从事水文水资源及地下水污染机理与修复方面的研究。E-mail:desertqy@163.com
基金资助:
国家重点基础研究发展计划（2010CB428804-1);中国地质科学院基本科研业务费项目(SYS1305);国土资源地质调查项目(1212010634611)

Spatial Distribution of Iodine in Underground Drinking Water and Discussion on Region-Specific Supply of Iodized Salt in the North China Plain

QIAN Yong, ZHANG Zhao-Ji, FEI Yu-Hong, CHEN Jing-Sheng, LI Ya-Song

Institute of Hydrogeology and Environmental Geology,Chinese Academy of Geological Sciences

Received:2013-05-17 Revised:2014-01-03 Online:2014-01-25 Published:2014-02-14
Contact: CHEN Jing-Sheng Institute of Hydrogeology and Environmental Geology,Chinese Academy of Geological Sciences E-mail:cjs1957@sina.com

摘要/Abstract

摘要： 自20世纪末实施全面加碘盐以消除碘缺乏病政策以来，我国碘缺乏病状况得到了极大改善，但高碘致病问题也引起了越来越多的关注和讨论。基于4 136组饮用地下水碘数据分析了华北平原饮用地下水碘的空间分布及其水文地质效应，并基于流行病学提出了饮用水合理碘含量限值的建议，据此将华北平原划分为极缺碘水区（≤4 μg•L^-1）、缺碘水区（>4～8 μg•L^-1）、适碘水区（>8～50 μg•L^-1）、可饮用碘水区（>50～100 μg•L^-1）、高碘水区（100～200 μg•L^-1）和超高碘水区（>200 μg•L^-1）。针对不同分区计算了食盐的合理加碘量，并从饮用水碘含量的角度将华北平原划分为需用加碘盐区、不需加碘盐区和不宜加碘盐区，这对于指导该区加碘盐政策的科学优化、解决食盐加碘带来的负面影响具有科学指导意义。研究发现，受水文地质条件和地下水循环特征控制，缺碘饮用地下水主要分布在燕山—太行山山前冲洪积平原及黄河冲洪积平原濮阳段，尤其近山的冲洪积平原是极缺碘饮用地下水的分布区；高碘地下水则主要分布在黄河冲洪积平原、东部滨海平原。计算结果表明，极缺碘水区与缺碘水区为需用加碘盐区，目前使用的20～50 μg•g^-1加碘盐能满足人体碘需求；适碘水和可饮用碘水区为不需加碘盐区，食盐碘含量应不大于9.2 μg•g^-1；高碘水和超高碘水区为不宜加碘盐区，建议仅供应无碘盐。

关键词: 华北平原, 高碘地下水, 加碘盐, 碘缺乏病（IDD）, 缺碘水

Abstract: The incidence of iodine deficiency disorder in China has been greatly reduced since the promotion of iodized salt in the late 1990s, however, the issue of excess iodine causing disorder is also attracting more and more concerns. A total of 4136 groups of water samples were collected from both shallow and deep underground dringking water sources in the North China Plain for analysis of iodine content to explore spatial distribution of iodine in groundwater and its hydrogeological effect. And based on the epidemiology, a reasonable iodine content in drinking water was put forward. On such a basis, the North China Plain was divided into six regions, namely, extremely iodine-deficient region (≤4μg•L^-1), iodine-deficient region (＞4-8μg•L^-1), iodine-proper region (＞8-50μg•L^-1), drinkable high iodine region (＞50-100μg•L^-1), high iodine region (＞100-200μg•L^-1) and extremely high iodine region (>200μg•L^-1). A proper iodine amendment rate in salt was worked out for each region. And based on iodine contents in groundwater, the plain could be divided into three regions, namely, iodine required region, iodine unrequired region and iodine-amendment unfit region. Such divisions are of some scientific significance for guiding optimization of salt iodization and solution of the problem of negative impact of the salt iodization. Results indicate that iodine-deficient groundwater is mainly distributed in the pediment alluvial-diluvial plain of the Yanshan Mountains-Taihang Mountains and the Puyang section of the Yellow River alluvial-diluvial plain; extremely iodine-deficient groundwater in the alluvial-diluvial plains adjacent to the mountains; and high iodine groundwater in the Yellow River alluvial-diluvial plain and the eastern coastal plain. The calculation shows that addition of iodine is required to the table salt for the extremely iodine-deficient regions and iodine-deficient regions, where the currently used 20-50μg•g^-1 iodized salt is adequate to meet the iodine demand of human body; there is no need to add any iodine to the table salt for the iodine-proper region and drinkable high iodine region, where the iodine content in the table salt should not exceed 9.2μg • g^-1; and it is not fit to add any iodine in the table salt in the high iodine regions and extremely high iodine region, where iodine-free salt is recommended.

Key words: North China Plain, high iodine groundwater, iodized salt, iodine deficiency disorder (IDD), iodine-deficient groundwater

中图分类号:

P592
X824

钱永, 张兆吉, 费宇红, 陈京生, 李亚松. 华北平原饮用地下水碘分布及碘盐分区供应探讨[J]. 生态与农村环境学报, 2014, 30(1): 9-14.

QIAN Yong, ZHANG Zhao-Ji, FEI Yu-Hong, CHEN Jing-Sheng, LI Ya-Song. Spatial Distribution of Iodine in Underground Drinking Water and Discussion on Region-Specific Supply of Iodized Salt in the North China Plain[J]. Journal of Ecology and Rural Environment, 2014, 30(1): 9-14.

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