Abstract
Based on global hydrological data, Taiwan has been classified as an area of water shortage. In some regions, and particularly during dry periods, groundwater is the only reliable water resource in Taiwan. This is particularly true for mountain regions. To determine the potential yield, and also to support sustainable management of groundwater resources, groundwater recharge must be estimated. The results of this study showed that there was a close relationship between measurements of the water table and the accumulated monthly precipitation in a well field close to Chien-Shih, Shinchu, NW Taiwan, which suggests that precipitation is the major source of recharge in the study area. However, the difference in the water table between the wet and dry seasons indicated that, in addition to precipitation, there is recharge from another stable source. We determined the pathway from, and the geological setting of, the recharge source areas by comparing precipitation events and temporal transformations in the water types. Out of four potential water types, the water corresponded to the Ca/Mg–SO4 2− type (III) at different points throughout the study period, indicating geochemical controls, such as dissolution–precipitation, dilution, cation exchange, silicate weathering, and mineralization. Meteoric water stored in the mountain region was another source of recharge that contributed to hydrochemical variability during the dry season. When this source was added, the mean δ18O value dropped from −15.8 to 1.4‰ in precipitation, from −9.6 to −7.8‰ in river water, from −9.1 to −6.9‰ in gully 1, from −7.4 to −5.8‰ in gully 2, and from −9.8 to −6.6‰ in groundwater. The isotopic compositions of Well C and Well W1 became lighter with additional recharge from the river, while those of Well E, Well W, and Well W2 became heavier during the rainy season. In the dry season, the isotopic composition was lighter in Well W1 and heavier in the other wells. It is worth noting that the isotopic composition of Well W1 was similar to that of the river, suggesting high connectivity between the river and Well W1, possibly through fractures.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Adams S, Titus R, Pietersen K, Tredoux G, Harris C (2001) Hydrochemical characteristics of aquifers near Sutherland in western Karoo, South Africa. J Hydrol 241:91–103
Alberto WD, Del Pilar DM, Valeria AM, Fabiana PS, Cecilia HA, De Los Angeles BM (2001) Pattern recognition techniques for the evaluation of spatial and temporal variations in water quality. A case study: Suquıa River Basin (Cordoba-Argentina). Water Res 35:2881–2894
Alcamo J, Döll P, Kaspar F, Siebert S (1997) Global change and global scenarios of water use and availability: an application of water GAP1.0. Report A9701. Center for Environmental Systems Research (CESR), University of Kassel, Germany
Aller L, Bennett T, Lehr JH, Petty RJ, Hackett G (1987) DRASTIC: a standardized system for evaluating ground water pollution potential using hydrogeological settings. EPA-600/2-87-035. EPA, Washington, DC
Appelo C, Postma D (1993) Groundwater and pollution. Balkema, Rotterdam
Barbieri M, Boschetti T, Petitta M, Marco T (2005) Stable isotope (2H, 18O and 87Sr/86Sr) and hydrochemistry monitoring for groundwater hydrodynamics analysis in a karst aquifer (Gran Sasso, Central Italy). Appl Geochem 20:2063–2081
Bekesi G, McConchie J (1999) Groundwater recharge modeling using the Monte Carlo technique, Manawatu region, New Zealand. J Hydrol 224:137–148
Belkhiri L, Boudoukha A, Mouni L, Baouz T (2010) Application of multivariate statistical methods and inverse geochemical modeling for characterization of groundwater—a case study: Ain Azel plain (Algeria). Geoderma 159:390–398
Bogaard T, Guglielmi Y, Marc V, Emblanch C, Bertrand C, Mudry J (2007) Hydrogeochemistry in landslide research: a review. Bull Soc Geol Fr 2:113–126
Burns DA (2002) Stormflow hydrography separation based on isotopes: the thrill is gone—what’s next? Hydrol Process 16:1515–1517
Chang SC, Lin TH, Lee CT (2009) On-road emission factors from light-duty vehicles measured in Hsuehshan Tunnel (12.9 km), the longest tunnel in Asia. Environ Monit Assess 153:187–200
Chapman JB, Lewis B, Litus G (2003) Chemical and isotopic evaluation of water sources to the fens of South Park, Colorado. Environ Geol 43:533–545
Cheung K, Klassen P, Mayer B, Goodarzi F, Aravena R (2010) Major ion and isotope geochemistry of fluids and gases from coalbed methane and shallow groundwater wells in Alberta, Canada. Appl Geochem 25:1307–1329
Choi BY, Yun ST, Mayer B, Chae GT, Kim KH, Kim K (2010) Identification of groundwater recharge sources and processes in a heterogeneous alluvial aquifer: results from multi-level monitoring of hydrochemistry and environmental isotopes in a riverside agricultural area in Korea. Hydrol Process 24:317–330
Clark ID, Fritz P (1997) Environmental isotopes in hydrogeology. Lewis Publishers, Boca Raton
Coleman ML, Shepherd TJ, Durham JJ, Rouse JE, Moore GR (1982) Reduction of water with zinc for hydrogen isotope analysis. Anal Chem 54:993–995
Epstein S, Mayeda T (1953) Variation of O-18 content of waters from natural sources. Geochim Cosmochim Acta 4:213–224
Gammons CH, Poulson SR, Pellicori DA, Reed PJ, Roesler AJ, Petrescu EM (2007) The hydrogen and oxygen isotopic composition of precipitation, evaporated mine water, and river water in Montana, USA. J Hydrol 328:319–330
Genereux DP, Hooper RP (1998) Oxygen and hydrogen isotopes in rainfall-runoff studies. In: Kendall C, McDonnell JJ (eds) Isotope in tracers in catchment hydrology. Elsevier, Amsterdam, pp 203–246
Gross EL (2008) A manual pumping test method for characterizing the productivity of drilled wells equipped with rope pumps. Master’s thesis, Michigan Technological University
Guglielmi Y, Vengeon JM, Bertrand C, Mudry J, Follacci JP, Giraud A (2002) Hydrogeochemistry: an investigation tool to evaluate infiltration into large moving rock masses (case study of La Clapie`re and Se´chilienne alpine landslides). Bull Eng Geol Environ 61:311–324
Gurrieri JT, Furniss G (2004) Estimation of groundwater exchange in alpine lakes using non-steady mass-balance methods. J Hydrol 297:187–208
Helena B, Pardo R, Vega M, Barrado E, Fernandez JM, Fernandez L (2000) Temporal evolution of groundwater composition in an alluvial aquifer (Pissuerga River, Spain) by principal component analysis. Water Res 34:807–816
International Atomic Energy Agency (1983) Guidebook on nuclear techniques in hydrology. Bernan Associates, Maryland
Join JL, Coudray J, Longworth K (1997) Using principal components analysis and Na/Cl ratios to trace groundwater circulation in a volcanic island: the example of reunion. J Hydrol 190:1–18
Kendall C, Coplen TB (2001) Distribution of oxygen-18 and deuterium in river waters across the United States. Hydrol Process 15:1363–1393
Lin PY, Tsai LL (2012a) A hydrochemical study of Hungtsaiping landslide area, Nantou. Taiwan. Environ Earth Sci 67:1045–1060
Lin PY, Tsai LL (2012) Estimating regional groundwater recharge from fluctuations of groundwater level, oxygen isotope and well yields at a well field near Chien-Shih area, Shinchu, Taiwan. In: 34th international geological congress unearthing our past and future—resourcing tomorrow. Brisbane, Queensland, Australia, 5–10 Aug 2012
Lin YB, Lin YP, Liu CW, Tan YC (2006) Mapping of spatial multi-scale sources of arsenic variation in groundwater on ChiaNan floodplain of Taiwan. Sci Total Environ 370:168–181
Liu CW, Lin KH, Kuo YM (2003) Application of factor analysis in the assessment of groundwater quality in a black foot disease area in Taiwan. Sci Total Environ 313:77–89
Liu TK, Chen CH, Yang TF, Lee M (2005) Tritium concentrations and radiocarbon ages of gushing groundwater from Hsuehshan Tunnel, Northern Taiwan. Terr Atmos Ocean Sci 14:909–917
Locsey KL, Cox ME (2003) Statistical and hydrochemical methods to compare basalt and basement rock-hosted groundwaters: Atheron Tablelands, northeastern Australia. Environ Geol 43:698–713
Lu HY, Peng TR, Liu TK, Wang CH, Huang CC (2006) Study of stable isotope for highly deformed aquifers in the Hsinchu-Miaoli area, Taiwan. Environ Geol 50:885–898
Macphersona GL, Sophocleousb M (2004) Fast ground-water mixing and basal recharge in an unconfined, alluvial aquifer, Konza LTER Site, Northeastern Kansas. J Hydrol 286:271–299
Maréchal JC, Etcheverry D (2003) The use of 3H and 18O tracers to characterize water inflows in Alpine tunnels. Appl Geochem 18:339–351
Montety VD, Marc V, Emblanch C, Malet JP, Bertrand C, Maquaire O (2007) Identifying the origin of groundwater and flow processes in complex landslides affecting black marls: insights from a hydrochemical survey. Earth Surf Process 32:32–48
Nath B, Jean JS, Lee MK, Yang HJ, Liu CC (2008) Geochemistry of high arsenic groundwater in Chia-Nan plain, Southwestern Taiwan: possible sources and reactive transport of arsenic. J Contam Hydrol 99:85–96
Ochsenkuehn KM, Kontoyannakos J, Ochsenkuehn PM (1997) A new approach to a hydrochemical study of groundwater flow. J Hydrol 194:64–75
Pellicori DA, Gammons CH, Poulson SR (2005) Geochemistry and stable isotope composition of the Berkeley pit lake and surrounding mine waters, Butte, Montana. Appl Geochem 20:2116–2137
Peng TR, Wang CH (2008) Identification of sources and causes of leakage on a zoned earth dam in northern Taiwan: hydrological and isotopic evidence. Appl Geochem 23:2438–2451
Peng TR, Wang CH, Liu TS, Houng YL (2002) Environmental and hydrological implications revealed by hydrogen and oxygen isotope compositions for the watershed of the Wuchi system in the Nantou area. J Agric Food Chem 40:238–253
Peng TR, Wang CH, Lai TC, Ho SK (2007) Using hydrogen, oxygen, and tritium isotopes to identify the hydrological factors contributing to landslides in a mountainous area, central Taiwan. Environ Geol 52:1617–1629
Peng TR, Wang CH, Huang CC, Fei LY, Arthur Chen CT, Hwong JL (2010) Stable isotopic characteristic of Taiwan’s precipitation: a case study of western Pacific monsoon region. Earth Planet Sci Lett 289:357–366
Pereira HG, Renca S, Sataiva J (2003) A case study on geochemical anomaly identification through principal component analysis supplementary projection. Appl Geochem 18:37–44
Robert MD (2009) Structural geology controls on groundwater flow: Lembang Fault case study, West Java, Indonesia. J Hydrol 17:1011–1023
Roesler AJ, Gammons CH, Druschel GK, Oduro H, Poulson SR (2007) Geochemistry of flooded underground mine workings influenced by bacterial sulfate reduction. Appl Geochem 12:211–235
Shapiro AM, Hsieh PA, Haeni FP (1999) Integrating multidisciplinary investigations in the characterization of fractured rock. In: Morganwalp DW,d Buxton HT (eds) US Geological Survey Toxic Substances Hydrology Program—Proceedings of the technical meeting, Charleston, South Carolina, pp 669–680
Sklash MG (1990) Environmental isotope studies of storm and snowmelt runoff generation. In: Anderson MG, Burt TP (eds) Process studies in hillslope hydrology. Wiley, Chichester, pp 401–435
Smerdon BD, Allen DM, Grasby SE, Berg MA (2009) An approach for predicting groundwater recharge in mountainous watersheds. J Hydrol 365:156–172
Taiwan Environmental Protection Administration (2004) The environmental investigations standard operating procedures and quality assurance manual. NIEA W104.51C. EPA, Taipei, Taiwan
Taiwan Environmental Protection Administration (2005) Requirements for Quality Management Plans. NIEA W102.50C. EPA, Taipei, Taiwan
Taiwan Environmental Protection Administration (2010) Evaluation of sampling and field—filtration method for the analysis of trace metals in groundwater. NIEA W103.54B. EPA, Taipei, Taiwan
Todd DK (1959) Groundwater hydrology. Wiley, London
Tu MK, Chen WC (1991) Explanatory text of the geological map of Taiwan—Chutung sheet. Central Geological Survey, Taiwan
Walton-Day K, Poeter E (2009) Investigating hydraulic connections and the origin of water in a mine tunnel using stable isotopes and hydrographs. Appl Geochem 24:2266–2282
Wang CH, Peng TR (2001) Hydrogen and oxygen isotopic compositions of Taipei precipitation: 1990–1998. West Pac Earth Sci 1:429–442
Wang CH, Kuo CH, Peng TR, Chen WF, Liu TK, Chiang CJ (2001a) Isotope characteristics of Taiwan groundwaters. West Pacif Earth Sci 1:415–428
Wang Y, Ma T, Luo Z (2001b) Geostatistical and geochemical analysis of surface water leakage into groundwater on regional scale: a case study in the Liulin karst system, northwestern China. J Hydrol 246:223–234
Warner NR, Kresse TM, Hays PD, Down A, Karr JD, Jackson RB, Vengosh A (2013) Geochemical and isotopic variations in shallow groundwater in areas of the Fayetteville Shale development, north-central Arkansas. Appl Geochem 35:207–220
Wireman M (2003) Characterization of ground-water resources in fractured-rock hydrogeologic settings. Ground Water Monit Rem 23:34–40
Acknowledgements
The authors would like to thank anonymous reviewers for their constructive comments. Moreover, the authors are deeply grateful to Dr. Chen, C. S. of Institute of Applied Geology, National Central University for their guidance and support throughout this project.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Lin, PY., Tsai, L.LY., Wang, CH. et al. Groundwater origins and recharge in a well field near Chien-Shih, Shinchu, Taiwan. Sustain. Water Resour. Manag. 3, 93–107 (2017). https://doi.org/10.1007/s40899-017-0119-2
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s40899-017-0119-2