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Hydrogeology Journal
Erschienen in: Hydrogeology Journal 7/2017

07.06.2017 | Report

Multi-tracer investigation of river and groundwater interactions: a case study in Nalenggele River basin, northwest China

verfasst von: Wei Xu, Xiaosi Su, Zhenxue Dai, Fengtian Yang, Pucheng Zhu, Yong Huang

Erschienen in: Hydrogeology Journal | Ausgabe 7/2017

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Abstract

Environmental tracers (such as major ions, stable and radiogenic isotopes, and heat) monitored in natural waters provide valuable information for understanding the processes of river–groundwater interactions in arid areas. An integrated framework is presented for interpreting multi-tracer data (major ions, stable isotopes (2H, 18O), the radioactive isotope 222Rn, and heat) for delineating the river–groundwater interactions in Nalenggele River basin, northwest China. Qualitative and quantitative analyses were undertaken to estimate the bidirectional water exchange associated with small-scale interactions between groundwater and surface water. Along the river stretch, groundwater and river water exchange readily. From the high mountain zone to the alluvial fan, groundwater discharge to the river is detected by tracer methods and end-member mixing models, but the river has also been identified as a losing river using discharge measurements, i.e. discharge is bidirectional. On the delta-front of the alluvial fan and in the alluvial plain, in the downstream area, the characteristics of total dissolved solids values, 222Rn concentrations and δ18O values in the surface water, and patterns derived from a heat-tracing method, indicate that groundwater discharges into the river. With the environmental tracers, the processes of river–groundwater interaction have been identified in detail for better understanding of overall hydrogeological processes and of the impacts on water allocation policies.
Vorheriger Artikel Geophysical, geochemical and hydrological analyses of water-resource vulnerability to salinization: case of the Uburu-Okposi salt lakes and environs, southeast Nigeria
Nächster Artikel Detecting inter-aquifer leakage in areas with limited data using hydraulics and multiple environmental tracers, including 4He, 36Cl/Cl, 14C and 87Sr/86Sr

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Literatur
Andersen MS, Acworth RI (2009) Stream-aquifer interactions in the Maules Creek catchment, Namoi Valley, new South Wales, Australia. Hydrogeol J 17(8):2005–2021CrossRef
Banks EW, Simmons CT, Love P, Shand AJ (2011) Assessing spatial and temporal connectivity between surface water and groundwater in a regional catchment: implications for regional scale water quantity and quality. J Hydrol 404:30–49CrossRef
Baskaran S, Ransley T, Brodie RS, Baker P (2009) Investigating groundwater–river interactions using environmental tracers. Aust J Earth Sci 56(1):13–19CrossRef
Bertin C, Bourg ACM (1994) Radon-222 and chloride as natural tracers of the infiltration of river water into an alluvial aquifer in which there is significant river/groundwater mixing. Environ Sci Technol 28(5):794–798CrossRef
Brodie RS, Sundaram B, Tottenham R, Hostetler S, Ransley T (2007) An adaptive management framework for connected groundwater-surface water resources in Australia. Bureau of Rural Sciences, Canberra, Australia
Brunner P, Simmons CT, Cook PG (2009) Spatial and temporal aspects of the transition from connection to disconnection between rivers, lakes and groundwater. J Hydrol 376(1–2):159–169CrossRef
Chapman T (1999) A comparison of algorithms for stream flow recession and baseflow separation. Hydrol Process 13:701–704CrossRef
Chen ZY, Wan L, Nie ZL et al (2006) Identification of groundwater recharge in the Heihe Basin using environmental isotopes (in Chinese with English abstract). Hydrogeol Eng Geol 6:9–14
Cook PG, Favreau G, Dighton JC, Tickell S (2003) Determining natural groundwater influx to a tropical river using radon, chlorofluorocarbons and ionic environmental tracers. J Hydrol 277(1–2):74–88CrossRef
Cook PG, Lamontagne S, Berhane D, Clark JF (2006) Quantifying groundwater discharge to Cockburn River, southeastern Australia, using dissolved gas tracers 222Rn and SF6. Water Resour Res 42(10):1–12CrossRef
Craig H (1961) Isotopic variations in meteoric waters. Science 133:1702–1703
Dai Z, Samper J (2004) Inverse problem of multicomponent reactive chemical transport in porous media: formulation and applications. Water Resour Res 40:W074071–W0740718CrossRef
Dai Z, Keating E, Gable CW, Levitt D, Heikoop J, Simmons A (2010) Stepwise inversion of a groundwater flow model with multi-scale observation data. Hydrogeol J 18:607–624CrossRef
Doctor D, Jr A, Petrič EC et al (2006) Quantification of karst aquifer discharge components during storm events through end-member mixing analysis using natural chemistry and stable isotopes as tracers. Hydrogeol J 14:1171–1191CrossRef
Ellins KK, Roman-Mas A, Lee R (1990) Using 222Rn to examine groundwater/surface discharge interaction in the Rio Grande de Manati, Puerto Rico. J Hydrol 115:319–341CrossRef
Fox GA, Durnford DS (2003) Unsaturated hyporheic zone flow in stream/aquifer conjunctive systems. Adv Water Res 26(9):989–1000CrossRef
Gordon RP, Lautz LK, Briggs MA, Mckenzie JM (2012) Automated calculation of vertical pore-water flux from field temperature time series using the vflux method and computer program. J Hydrol 420–421(4):142–158
Harvey JW, Wagner BJ, Bencala KE (1996) Evaluating the reliability of the stream tracer approach to characterize stream–subsurface water exchange. Water Resour Res 32(8):2441–2451CrossRef
Hatch CE, Fisher AT, Revenaugh JS et al (2006) Quantifying surface water groundwater interactions using time series analysis of streambed thermal records: method development. Water Resour Res 42(10):1–14CrossRef
Hatch CE, Fisher AT, Ruehl CR, Stemler G (2010) Spatial and temporal variations in streambed hydraulic conductivity quantified with time-series thermal methods. J Hydrol 389(3–4):276–288CrossRef
Intissar F, Kamel Z, Kamel A, Mohamed A (2013) Hydrogeochemical investigation of surface and groundwater composition in an irrigated land in central Tunisia. J Afr Earth Sci 78:16–27CrossRef
Kalbus E, Reinstorf F, Schirmer M (2006) Measuring methods for groundwater–surface water interactions: a review. Hydrol Earth Sys Sci 10(6):873–887CrossRef
Keery J, Binley A, Crook N et al (2007) Temporal and spatial variability of groundwater surface water fluxes: development and application of an analytical method using temperature time series. J Hydrol 336(1/2):1–16CrossRef
Kluge T, Ilmberger J, Von-Rohden C, Aeschbach-Hertig W (2007) Tracing and quantifying groundwater inflow into lakes using a simple method for radon-222 analysis. Hydrol Earth Syst Sci Discuss 11:1621–1631CrossRef
Lamontagne S, Cook PG (2007) Estimation of hyporheic water residence time in situ using 222Rn disequilibrium. Limnol Oceanogr Methods 5:407–416CrossRef
Li J, Wang H, Wei L (2007) Isotopic and hydrochemical characteristics of groundwater in the Golmud River basin (in Chinese with English abstract). Northwest Geol 40(4):94–100
Martinez JL, Raiber M, Cendón DI (2017) Using 3D geological modelling and geochemical mixing models to characterise alluvial aquifer recharge sources in the Upper Condamine River catchment, Queensland, Australia. Sci Total Environ 574:1–18CrossRef
Mitchell-Bruker SM (1993) Modeling steady state groundwater and surface water interactions. PhD Thesis, Indiana Univ, Bloomington, IN, 94 pp
Otz MH, Otz HK, Siegel DI (2003) Surface water/groundwater interaction in the Piora aquifer, Switzerland: evidence from dye tracing tests. Hydrogeol J 11(2):228–239CrossRef
Payn RA, Gooseff MN, Mcglynn BL, Bencala KE, Wondzell SM (2009) Channel water balance and exchange with subsurface flow along a mountain headwater stream in Montana, United States. Water Resour Res 45(11):355–355CrossRef
Schmidt A, Stringer CE, Haferkorn U, Schubert M (2009) Quantification of groundwater discharge into lakes using radon-222 as naturally occurring tracer. Environ Geol 56:855–863CrossRef
Smerdon BD, Gardner WP, Harrington GA, Tickell SJ (2012) Identifying the contribution of regional groundwater to the baseflow of a tropical river (Daly River, Australia). J Hydrol 464:107–115CrossRef
Sophocleous M (2002) Interactions between groundwater and surface water: the state of the science. Hydrogeol J 10:52–67CrossRef
Stallman RW (1965) Steady one-dimensional fluid flow in a semi-infinite porous medium with sinusoidal surface temperature. J Geophys Res 70(12):2821–2827CrossRef
Stellato L, Petrella E, Terrasi F, Belloni P, Belli M, Sansone U, Celico F (2008) Some limitations in using 222Rn to assess river–groundwater interactions: the case of Castel di Sangro alluvial plain (central Italy). Hydrogeol J 16:701–712CrossRef
Su X, Xu W, Yang F, Zhu P (2015) Using new mass balance methods to estimate gross surface water and groundwater exchange with naturally occurring tracer 222Rn in data poor regions: a case study in northwest China. Hydrol Process 29(6):979–990CrossRef
Wang W, Dai Z, Zhao Y et al (2016) A quantitative analysis of hydraulic interaction processes in stream–aquifer systems. Scientific Rep 6:19876. doi:10.​1038/​srep19876
Weltje GJ (1997) End-member modeling of compositional data: numerical-statistical algorithms for solving the explicit mixing problem. Math Geol 29:503–549CrossRef
Winter TC, Harvey JW, Franke OL, Alley WM (1998) Groundwater and surface water: a single resource. US Geol Surv Circ 1139
Woessner WW (2000) Stream and fluvial plain ground water interactions: rescaling hydrogeologic thought. Ground Water 38(3):423–429CrossRef
Wu Y, Wen X, Zhang Y (2004) Analysis of the exchange of groundwater and river water by using radon-222 in the middle Heihe Basin of northwestern China. Environ Geol 54(5):647–653CrossRef
Zhu L, Gong H, Dai Z et al (2015) An integrated assessment of the impact of precipitation and groundwater on vegetation growth in arid and semiarid areas. Environ Earth Sci 74:5009–5021CrossRef
Metadaten
Titel
Multi-tracer investigation of river and groundwater interactions: a case study in Nalenggele River basin, northwest China
verfasst von
Wei Xu
Xiaosi Su
Zhenxue Dai
Fengtian Yang
Pucheng Zhu
Yong Huang
Publikationsdatum
07.06.2017
Verlag
Springer Berlin Heidelberg
Erschienen in
Hydrogeology Journal / Ausgabe 7/2017
Print ISSN: 1431-2174
Elektronische ISSN: 1435-0157
DOI
https://doi.org/10.1007/s10040-017-1606-0

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