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Hydrogeology Journal

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01.05.2015 | Report

Assessment of well vulnerability for groundwater source protection based on a solute transport model: a case study from Jilin City, northeast China

verfasst von: Huan Huan, Jinsheng Wang, Desheng Lai, Yanguo Teng, Yuanzheng Zhai

Erschienen in: Hydrogeology Journal | Ausgabe 3/2015

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Abstract

Well vulnerability assessment is essential for groundwater source protection. A quantitative approach to assess well vulnerability in a well capture zone is presented, based on forward solute transport modeling. This method was applied to three groundwater source areas (Jiuzhan, Hadawan and Songyuanhada) in Jilin City, northeast China. The ratio of the maximum contaminant concentration at the well to the released concentration at the contamination source (c _max/c ₀) was determined as the well vulnerability indicator. The results indicated that well vulnerability was higher close to the pumping well. The well vulnerability in each groundwater source area was low. Compared with the other two source areas, the cone of depression at Jiuzhan resulted in higher spatial variability of c _max/c ₀ and lower minimum c _max/c ₀ by three orders of magnitude. Furthermore, a sensitivity analysis indicated that the denitrification rate in the aquifer was the most sensitive with respect to well vulnerability. A process to derive a NO₃−N concentration at the pumping well is presented, based on determining the maximum nitrate loading limit to satisfy China’s drinking-water quality standards. Finally, the advantages, disadvantages and prospects for improving the precision of this well vulnerability assessment approach are discussed.

Vorheriger Artikel The diagnostic plot analysis of artesian aquifers with case studies in Table Mountain Group of South Africa

Nächster Artikel Functional parameterization for hydraulic conductivity inversion with uncertainty quantification

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ASTM (1996) Standard guide for calibrating a ground-water flow model application. American Society for Testing and Materials D5981–D5996 Standard, ASTM, West Conshohocken, PA

Brouye`re S, Jeannin PY, Dassargues A et al (2001) Evaluation and validation of vulnerability concepts using a physically based approach. In: Mudry J, Zwalen F (eds) Proceedings of the 7th Conference on Limestone Hydrology and Fissured Media, Besancxon, France, 20–22 September. Université de Franche-Comte, Sciences et Techniques de l’ Environnement, Besancxon, France, pp 67–72

Butscher C, Huggenberger P (2009) Enhanced vulnerability assessment in karst areas by combining mapping with modeling approaches. Sci Total Environ 407(3):1153–1163CrossRef

Cheng Y, Yingying Y, Gregory H et al (2010) Quantitative assessment of groundwater vulnerability using index system and transport simulation, Huangshuhe catchment, China. Sci Total Environ 408(24):6108–6116CrossRef

Debernardi L, De Luca DA, Lasagna M (2005) Il processo di denitrificazione naturale nelle acque sotterranee in Piemonte [Natural denitrification in groundwater in the western sector of the Po Plain (northern Italy)]. Paper ID 176, Proceedings of Aquifer vulnerability and Risk, 2nd International Workshop and 4th National Congress on the Protection and Management of Groundwater, Reggia di Colorno (PR), Italy, 21–23 September, 27 pp

Debernardi L, De Luca DA, Lasagna M (2008) Correlation between nitrate concentration in groundwater and parameters affecting aquifer intrinsic vulnerability. Environ Geol 55:539–558CrossRef

Dong WH, Lin XY (2004) Analysis on the influence factors of the nitrogen pollution in shallow groundwater: a case in the north high plain of Songhua River in Songnen Basin. J Jilin Univ (Earth Sci Ed) 34(2):231–235

Dreyfus G (2005) Neural networks: methodology and applications. Springer, Berlin, 497 pp

Environmental Geology Monitoring Station of Jilin Province, China (1996) Groundwater dynamic monitoring in Jilin Province between 1991 and 1995. EGMS, Jilin Province, China

Environmental Geology Monitoring Station of Jilin Province, China (2001) Groundwater dynamic monitoring in Jilin Province between 1996 and 2000. EGMS, Jilin Province, China

Environmental Geology Monitoring Station of Jilin Province, China (2008) Hydrogeological investigation report in Jilin City. EGMS, Jilin Province, China

Fetter CW (1999) Contaminant hydrogeology, 2nd edn. Prentice-Hall, London

Foster S, Hirata R, Gomes D, D´elia M, Paris M (2002) Protección de la Calidad del Agua Subterránea [Protection of groundwater quality]. GW-MATE-UNESCO-World Bank, Washington, DC, 115 pp

Frind E, Molson J, Rudolph D (2006) Well vulnerability: a quantitative approach for source water protection. Ground Water 44(5):732–742

Gelhar LW, Welty C, Rehfeldt KR (1992) A critical review of data on field-scale dispersion in aquifers. Water Resour Res 28(7):1955–1974CrossRef

Gogu RC, Dassargues A (2000) Sensitivity analysis for the EPIK method of vulnerability assessment in a small karstic aquifer, southern Belgium. Hydrogeol J 8:337–345CrossRef

Igor M, Pieter JS (2011) Quantifying the vulnerability of well fields towards anthropogenic pollution: the Netherlands as an example. J Hydrol 398(3–4):260–276

Johnson AI, Morris DA (1962) Physical and hydrologic properties of water bearing deposits from core holes in the Banos-Kettleman City area, California. U Geol Surv Open-File Rep 27, 182 pp

Kitanidis P (1994) The concept of the dilution index. Water Resour Res 30(7):2011–2026CrossRef

Korom SF (1992) Natural denitrification in the saturated zone: a review. Water Resour Res 28(6):1657–1668CrossRef

Liang XJ, Xiao CL, Sheng HX et al (2007) Migration and transformation of ammonia-nitrite-nitrates in groundwater in the city of Jilin. J Jilin Univ (Earth Sci Ed) 37(2):335–345

Lim JW, Bae GO, Lee KK (2009) Groundwater vulnerability assessment by determining maximum contaminant loading limit in the vicinity of pumping wells. Geosci J 13(1):79–85CrossRef

McElwee CD (1982) Sensitivity analysis and the ground-water inverse problem. Ground Water 20(6):723–735CrossRef

Ministry of Environmental Protection of the People’s Republic of China (2011) Groundwater pollution prevention and control planning (2011–2020). http://www.zhb.gov.cn/gkml/hbb/bwj/201111/t20111109_219754.htm. Accessed 11 September 2011

Molsona JW, Frind EO (2012) On the use of mean groundwater age, life expectancy and capture probability for defining aquifer vulnerability and time-of-travel zones for source water protection. J Contam Hydrol 127(1–4):76–87CrossRef

Neukum C, Azzam R (2009) Quantitative assessment of intrinsic groundwater vulnerability to contamination using numerical simulations. Sci Total Environ 408(2):145–254CrossRef

Neupauer RM, Wilson JL (2004) Numerical implementation of a backward probabilistic model of groundwater contamination. Ground Water 42(2):175–189CrossRef

Neupauer RM, Wilson JL (2005) Backward probability model using multiple observations of contaminant to identify groundwater contamination sources at the Massachusetts Military Reservation. Water Resour Res 41:1–14CrossRef

Nobre RCM, Rotunno OC, Mansur WJ et al (2007) Groundwater vulnerability and risk mapping using GIS, modeling and a fuzzy logic tool. J Contam Hydrol 94(3–4):277–292CrossRef

Rainer E, Wolfgang N, Rainer H (2012) Probabilistic exposure risk assessment with advective–dispersive well vulnerability criteria. Adv Water Resour 36:121–132CrossRef

Stigter TY, Ribeiro L, Carvalho DAMM (2006) Evaluation of an intrinsic and a specific vulnerability assessment method in comparison on a regional scale. J Hydrogeol 14(3):79–99CrossRef

US EPA (1989) Risk assessment guidance for superfund, vol 1: human health evaluation manual (part A). EPA/540/1–89/002, US EPA, Washington, DC

Vassolo S, Kinzelbach W, Schafer W (1998) Determination of a well head protection zone by stochastic inverse modelling. J Hydrol 206(3–4):268–280CrossRef

Wang JS, Wang P, Liu WC (2004) Numerical simulation method for delineating protection zones of groundwater wellfields. Hydrogeol Eng Geol 31(4):83–86

Zwahlen F (ed) (2004) COST Action 620: vulnerability and risk mapping for the protection of carbonate (karst) aquifers. Final report, Office of the Official Publications of the European Communities, Brussels, Belgium, 297 pp

Titel: Assessment of well vulnerability for groundwater source protection based on a solute transport model: a case study from Jilin City, northeast China
verfasst von: Huan Huan
Jinsheng Wang
Desheng Lai
Yanguo Teng
Yuanzheng Zhai
Publikationsdatum: 01.05.2015
Verlag: Springer Berlin Heidelberg
Erschienen in: Hydrogeology Journal / Ausgabe 3/2015
Print ISSN: 1431-2174
Elektronische ISSN: 1435-0157
DOI: https://doi.org/10.1007/s10040-014-1211-4

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