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科学通报 2013

降雨期间岩溶地下水化学组分的来源及运移路径

, PP. 1755-1763

杨平恒,袁道先,叶许春,谢世友,陈雪彬,刘子琦

Keywords: 岩溶地下水,化学组分,来源,运移路径,扩散流,管道流

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Abstract:

对降雨期间重庆青木关岩溶地下水系统出口姜家泉的水物理化学动态变化进行监测,获取高分辨率的数据,运用主成分分析法探索岩溶地下水化学组分的来源;结合水物理化学数据的变异系数,探讨化学组分在岩溶含水层中的运移路径.结果表明,水-岩作用和农业活动,以及水土流失是研究区岩溶地下水化学组分的主要来源.K+,Na+,NO3-,Cl-和PO43-等离子从地表输入后,与碳酸盐岩溶解产生的Ca2+,Mg2+,Sr2+和HCO3-等一并存储于裂隙、孔隙和溶隙等岩溶非饱和带中,受岩溶非饱和带的调蓄.这些离子在降雨期间随扩散流补给地下河,其浓度较为稳定,变异系数低.而全Fe、全Mn和Al3+等未经岩溶非饱和带的调蓄,在降雨期间随坡面漫流直接通过落水洞灌入地下河,其浓度极不稳定,变异系数高.农业活动和水土流失输入的物质严重威胁着岩溶地下水生态环境和当地居民的健康,因而有必要加强岩溶生态系统管理工作,从控制岩溶地下水外界物质输入端的源头抓起.

References

[1]	1 袁道先. 我国西南岩溶石山的环境地质问题. 大自然探索, 1996, 15: 21-23
[2]	2 袁道先, 薛禹群, 傅家谟, 等. 防止我国西南岩溶地区地下河变成“下水道”的对策与建议. 中国科学院院士建议, 2007, 4: 1-14
[3]	3 沈照理, 朱宛华, 钟佐燊. 水文地球化学基础. 北京: 地质出版社, 1993
[4]	7 郭永海, 沈照理, 钟佐燊. 河北平原地下水化学环境演化的地球化学模拟. 中国科学D辑: 地球科学, 1997, 27: 360-365
[5]	9 Ford D C, Williams P W. Karst Geomorphology and Hydrology. Chichester: Wiley, 2007
[6]	10 袁道先, 蔡桂鸿. 岩溶环境学. 重庆: 重庆出版社, 1988
[7]	15 Langmuir D. The geochemistry of some carbonate ground waters in central Pennsylvania. Geochim Cosmochim Acta, 1971, 35: 1023-1045
[8]	16 Hess J, White W. Storm response of the karstic carbonate aquifer of southcentral Kentucky. J Hydrol, 1988, 99: 235-252
[9]	17 Ternan J L. Comment on the use of a calcium hardness variablity index in the study of carbonate aquifers: With reffernce to the Central Pennines, England. J Hydrol, 1972, 16: 317-321
[10]	21 Koonce J E, Yu Z, Farnham I M, et al. Geochemical interpretation of groundwater flow in the southern Great Basin. Geosphere, 2006, 2: 88-101
[11]	22 Lamouroux C, Hani A. Identification of groundwater flow paths in complex aquifer systems. Hydrol Process, 2006, 20: 2971-2987
[12]	23 Omo-Irabor O O, Olobaniyi S B, Oduyemli K, et al. Surface and groundwater water quality assessment using multivariate analytical methods: A case study of the Western Niger Delta, Nigeria. Phys Chem Earth, 2008, 33: 666-673
[13]	24 Rao N S, Rao J P, Subrahmanyam A. Principal component analysis in groundwater quality in a developing urban area of Andhra Pradesh. J Geol Soc India, 2007, 69: 959-969
[14]	27 Herman E K, Toran L, White W B. Quantifying the place of karst aquifers in the groundwater to surface water continuum: A time series analysis study of storm behavior in Pennsylvania water resources. J Hydrol, 2009, 376: 307-317
[15]	28 中华人民共和国国家质量监督检验检疫总局, 国国家标准化管理委员会. 饮用天然矿泉水检测方法(GB/T 8538-2008). 北京: 中国标准出版社, 2008
[16]	32 Peterson E W, Davis R K, Brahana J V, et al. Movement of nitrate through regolith covered karst terrane, northwest Arkansas. J Hydrol, 2002, 256: 35-47
[17]	34 Pronk M, Goldscheider N, Zopfi J. Dynamics and interaction of organic carbon, turbidity and bacteria in a karst aquifer system. Hydrogeol J, 2006, 14: 473-484
[18]	38 Atkinson T. Diffuse flow and conduit flow in limestone terrain in the Mendip Hills, Somerset (Great Britain). J Hydrol, 1977, 35: 93-110
[19]	4 Swarzenski P W, Reich C D, Spechler R M, et al. Using multiple geochemical tracers to characterize the hydrogeology of the submarine spring off Crescent Beach, Florida. Chem Geol, 2001, 179: 187-202
[20]	5 Bau M, Usui A, Pracejus B, et al. Geochemistry of low-temperature water-rock interaction: Evidence from natural waters, andesite, and iron-oxyhydroxide precipitates at Nishiki-numa iron-spring, Hokkaido, Japan. Chem Geol, 1998, 151: 293-307
[21]	6 Lang Y C, Liu C Q, Zhao Z Q, et al. Geochemistry of surface and ground water in Guiyang, China: Water/rock interaction and pollution in a karst hydrological system. Appl Geochem, 2006, 21: 887-903
[22]	8 Wicks C M, Engeln J F. Geochemical evolution of a karst stream in Devils Icebox Cave, Missouri, USA. J Hydrol, 1997, 198: 30-41
[23]	11 刘丛强, 郎赟超, 李思亮, 等. 喀斯特生态系统生物地球化学过程与物质循环研究: 重要性、现状与趋势. 地学前缘, 2009, 16: 1-12
[24]	12 刘再华, Dreybrodt W, 王海静. 一种由全球水循环产生的可能重要的CO2汇. 科学通报, 2007, 52: 2418-2422
[25]	13 袁道先, 刘再华, 林玉石, 等. 中国岩溶动力系统. 北京: 地质出版社, 2002
[26]	14 Shuster E T, White W B. Seasonal fluctuations in the chemistry of lime-stone springs: A possible means for characterizing carbonate aquifers. J Hydrol, 1971, 14: 93-128
[27]	18 杨平恒. 重庆青木关地下河系统的水文地球化学特征及悬浮颗粒物运移规律. 博士学位论文. 重庆: 西南大学, 2010
[28]	19 Pu J B, Yuan D X, He Q F, et al. High-resolution monitoring of nitrate variations in a typical subterranean karst stream, Chongqing, China. Environ Earth Sci, 2011, 64: 1985-1993
[29]	20 Carroll S, Goonetilleke A. Assessment of high density of onsite wastewater treatment systems on a shallow groundwater coastal aquifer using PCA. Environmetrics, 2005, 16: 257-274
[30]	25 杨平恒, 袁道先, 袁文昊, 等. 以PCA揭示降雨期间岩溶地下水水文地球化学的形成. 科学通报, 2010, 55: 788-797
[31]	26 Jacobsona R L, Langmuir D. Controls on the quality variations of some carbonate spring waters. J Hydrol, 1974, 23: 247-265
[32]	29 张文霖. 主成分分析在SPSS中的操作应用. 市场研究, 2005, 12: 31-34
[33]	30 刘再华. 岩溶水文地球化学研究中pH野外测定的必要性. 中国岩溶, 1990, 9: 310-317
[34]	31 Monteagudo L, Moreno J L, Picazo F. River eutrophication: Irrigated vs. non-irrigated agriculture through different spatial scales. Water Res, 2012, 46: 2759-2771
[35]	33 Shevenell L, McCarthy J F. Effects of precipitation events on colloids in a karst aquifer. J Hydrol, 2002, 255: 50-68
[36]	35 Fournier M, Massei N, Bakalowicz M, et al. Using turbidity dynamics and geochemical variability as a tool for understanding the behavior and vulnerability of a karst aquifer. Hydrogeol J, 2007, 15: 689-704
[37]	36 Atteia O, Kozel R. Particle size distributions in waters from a karstic aquifer: From particles to colloids. J Hydrol, 1997, 201: 102-119
[38]	37 杨平恒, 刘子琦, 贺秋芳. 降雨条件下岩溶泉水中悬浮颗粒物的运移特征及来源分析. 环境科学, 2012, 33: 3376-3381
[39]	39 杨平恒, 袁道先, 任幼蓉, 等. 川东平行岭谷区典型岩溶含水系统中NO3?的存储和运移. 环境科学, 2012, 33: 3124-3131

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