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Hydrogeology Journal

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04.12.2017 | Report

Hydrogeochemical characteristics and sources of salinity of the springs near Wenquanzhen in the eastern Sichuan Basin, China

verfasst von: Juan Guo, Xun Zhou, Lidong Wang, Yuqi Zhang, Xiaowei Shen, Haiyan Zhou, Shen Ye, Bin Fang

Erschienen in: Hydrogeology Journal | Ausgabe 4/2018

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Abstract

Natural springs have the potential to provide important information on hydrogeochemical processes within aquifers. This study used traditional and classic technical methods and procedures to determine the characteristics and evolution of springs to gain further knowledge on the differences between hot saline springs and cold fresh springs. In a short river segment near Wenquanzhen in the eastern Sichuan Basin, southwest China, several natural springs coexist with total dissolved solids (TDS) ranging from less than 1 to 15 g/L and temperatures from 15 to 40 °C. The springs emanate from the outcropping Lower and Middle Triassic carbonates in the river valley cutting the core of an anticline. The cold springs are of Cl·HCO₃-Na·Ca and Cl·SO₄-Na types, and the hot saline springs are mainly of Cl-Na type. The chemistry of the springs has undergone some changes with time. The stable hydrogen and oxygen isotopes indicate that the spring waters are of a meteoric origin. The salinity of the springs originates from dissolution of minerals, including halite, gypsum, calcite and dolomite. The evolution of the springs involves the following mechanisms: the groundwater receives recharge from infiltration of precipitation, then undergoes deep circulation in the core of the anticline (incongruent dissolution of the salt-bearing strata occurs), and emerges in the river valley in the form of hot springs with high TDS. Groundwater also undergoes shallow circulation in the northern and southern flanks of the anticline and appears in the river valley in the form of cold springs with low TDS.

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Afsin M, Allen DM, Kirste D, Durukan UG, Gurel A, Oruc O (2014) Mixing processes in hydrothermal spring systems and implications for interpreting geochemical data: a case study in the Cappadocia region of Turkey. Hydrogeol J 22(1):7–23CrossRef

Alfaro C, Wallace M (1994) Origin and classification of springs and historical review with current applications. Environ Geol 24(2):112–124CrossRef

Allen DM, Bayer P, Ferguson G, Blum P (2014) Preface: Hydrogeology of shallow thermal systems. Hydrogeol J 22(1):1–6CrossRef

Bagheri R, Nadri A, Raeisi E, Shariati A, Mirbagheri M, Bahadori F (2014a) Chemical evolution of a gas-capped deep aquifer, southwest of Iran. Environ Earth Sci 71(7):3171–3180CrossRef

Bagheri R, Nadri A, Raeisi E, Kazemi GA, Eggenkamp HGM, Montaseri A (2014b) Origin of brine in the Kangan gasfield: isotopic and hydrogeochemical approaches. Environ Earth Sci 72(4):1055–1072CrossRef

Barbier E (2002) Geothermal energy technology and current status: an overview. Renew Sust Energ Rev 6(1–2):3–65CrossRef

Benavente O, Tassi F, Reich M, Aguilera F, Capecchiacci F, Gutierrez F, Vaselli O, Rizzo A (2016) Chemical and isotopic features of cold and thermal fluids discharged in the southern volcanic zone between 32.5°S and 36°S: insights into the physical and chemical processes controlling fluid geochemistry in geothermal systems of central Chile. Chem Geol 420:97–113. https://doi.org/10.1016/j.chemgeo.2015.11.010 CrossRef

Bryan K (1919) Classification of Springs. J Geol 27 (7):522–561

Cartwright I, Weaver TR, Fulton S, Nichol C, Reid M, Cheng X (2004) Hydrogeochemical and isotopic constraints on the origins of dryland salinity, Murray Basin, Victoria, Australia. Appl Geochem 19(8):1233–1254CrossRef

Chiesi M, De Waele J, Forti P (2010) Origin and evolution of a salty gypsum/anhydrite karst spring: the case of Poiano (northern Apennines, Italy). Hydrogeol J 18(5):1111–1124CrossRef

Clayton RN, Steiner A (1975) Oxygen isotope studies of the geothermal system at Wairakei, New Zealand. Geochim Cosmochim Acta 39(8):1179–1186CrossRef

Craig H (1961) Isotopic variations in meteoric waters. Science 133(346):1702–1703CrossRef

Dresel PE, Rose AW (2010) Chemistry and origin of oil and gas well brines in western Pennsylvania. Pennsylvania Geological Survey, Pittsburgh, PA

Edmunds WM, Smedley PL (2000) Residence time indicators in groundwater: the East Midlands Triassic sandstone aquifer. Appl Geochem 15(6):737–752CrossRef

Edmunds WM, Bath AH, Miles DL (1982) Hydrochemical evolution of the East Midlands Triassic sandstone aquifer, England. Geochim Cosmochim Acta 46(11):2069–2081CrossRef

Edmunds WM, Guendouz AH, Mamou A, Moulla A, Shand P, Zouari K (2003) Groundwater evolution in the continental Intercalaire aquifer of southern Algeria and Tunisia: trace element and isotopic indicators. Appl Geochem 18(6):805–822CrossRef

Eseme E, Agyingi CM, Foba-Tendo J (2002) Geochemistry and genesis of brine emanations from Cretaceous strata of the Mamfe Basin, Cameroon. J Afr Earth Sci 35(4):467–476CrossRef

Ettazarini S (2005) Processes of water–rock interaction in the Turonian aquifer of Oum Er-Rabia Basin, Morocco. Environ Geol 49(2):293–299. https://doi.org/10.1007/s00254-005-0088-x CrossRef

Fan QS, Ma YQ, Cheng HD, Wei HC, Yuan Q, Qin ZJ, Shan FS (2015) Boron occurrence in halite and boron isotope geochemistry of halite in the Qarhan Salt Lake, western China. Sediment Geol 322:34–42CrossRef

Farid I, Zouari K, Rigane A, Beji R (2015) Origin of the groundwater salinity and geochemical processes in detrital and carbonate aquifers: case of Chougafiya basin (central Tunisia). J Hydrol 530:508–532CrossRef

Friedman I (1953) Deuterium content of natural waters and other substances. Geochim Cosmochim Acta 4(1–2):89–103CrossRef

Glazier DS (2009) Springs. In: Likens GE (ed) Encyclopedia of inland waters. Elsevier, Oxford pp 734–756

Han Y, Huh Y (2009) A geochemical reconnaissance of the Duman (Tumen) River and the hot springs of Mt. Baekdu (Changbai): weathering of volcanic rocks in mid-latitude setting. Chem Geol 264(1–4):162–172CrossRef

Han Y, Wang G, Charles AC, HuW BY, Zhang Z, Liu Y (2013) Hydrogeochemical evolution of Ordovician limestone groundwater in Yanzhou, North China. Hydrol Process 27(16):2247–2257CrossRef

Hendry MJ, Wassenaar LI (2000) Controls on the distribution of major ions in pore waters of a thick surficial aquitard. Water Resour Res 36(2):503–513. https://doi.org/10.1029/1999WR900310 CrossRef

Huang KK, Zhong YJ, Huang SJ, Li XN, Feng MS (2016) Saddle-dolomite-bearing fracture fillings and records of hot brine activity in the Jialingjiang Formation, Libixia section, Hechuan area of Chongqing City. Acta Geol Sin 90(1):195–208CrossRef

Jean JS, Liao L, Kar S, Liu CC, Li Z (2016) Hydrochemistry of hot springs in geothermal fields of central, northern, and northeastern Taiwan: implication on occurrence and enrichment of arsenic. Environ Earth Sci 75(19):1316. https://doi.org/10.1007/s12665-016-6128-x CrossRef

Kloppmann W, Négrel P, Casanova J, Klinge H, Schelkes K, Guerrot C (2001) Halite dissolution derived brines in the vicinity of a Permian salt dome (N German Basin) evidence from boron, strontium, oxygen, and hydrogen isotopes. Geochim Cosmochim Acta 65(22):4087–4101CrossRef

Knauth LP (1988) Origin and mixing history of brines, Palo Duro Basin, Texas, USA. Appl Geochem 3(5):455–474CrossRef

Kpegli KAR, Alassane A, Trabelsi R, Zouari K, Boukari M, Mama D, Dovonon FL, Yoxi YV, Toro-Espitia LE (2015) Geochemical processes in Kandi Basin, Benin, West Africa: a combined hydrochemistry and stable isotopes approach. Quat Int 369:99–109CrossRef

Li CJ, Yang LZ, Zhou X, Ming C (1992) A study of the evaluation of deep formation brine resources. Geological Publishing House, Beijing

Li L, Tan XC, Cao J, Zou C, Ding X, Yang G, Ying DL (2014) Origins of evaporites in the middle Triassic Leikoupo formation of the Sichuan Basin, southwest China and their geological implications. Carbonates Evaporites 29(1):55–63CrossRef

Liang F, Bai WH, Zou CN, Wang HY, Wu J, Ma C, Zhang Q, Guo W, Sun SS, Zhu YM, Cui HY, Liu DX (2016) Shale gas enrichment pattern and exploration significance of well WuXi-2 in northeast Chongqing, NE Sichuan basin. Pet Explor Dev 43(3):386–394CrossRef

Lin Y (1999) Storage characteristics of the Triassic ground brine in Sichuan Basin and the determination factors of its enrichment (in Chinese). J Salt Lake Res 31:287–293

Lin Y (2006) On the hydrogeological conditions of groundwater in the Triassic system of Sichuan Basin. J Salt Lake Res 14(1):1–8

Liu WG, Xiao YK, Wang QZ, Qi HP, Wang YH, Zhou YM, Shirodkar PV (1997) Chlorine isotopic geochemistry of salt lakes in the Qaidam Basin, China. Chem Geol 136(3–4):271–279CrossRef

Luders V, Plessen B, Romer RL, Weise SM, Banks DA, Hoth P, Dulski P, Schettler G (2010) Chemistry and isotopic composition of Rotliegend and upper carboniferous formation waters from the north German Basin. Chem Geol 276(3–4):198–208CrossRef

Marie A, Vengosh A (2001) Sources of salinity in ground water from Jericho area, Jordan Valley. Ground Water 39(2):240–248CrossRef

Naik PK, Awasthi AK, Mohan PC (2002) Springs in a headwater basin in the Deccan trap country of the western Ghats, India. Hydrogeol J 10(5):553–565CrossRef

Perez ES (1996) Springs in Spain: classification according to their flows and lithologies and their hydraulic contributions. Ground Water 34(6):1033–1041CrossRef

Pilla G, Sacchi E, Zuppi G, Braga G, Ciancetti G (2006) Hydrochemistry and isotope geochemistry as tools for groundwater hydrodynamic investigation in multilayer aquifers: a case study from Lomellina, Po plain, south-western Lombardy, Italy. Hydrogeol J 14(5):795–808. https://doi.org/10.1007/s10040-005-0465-2 CrossRef

Pinti DL, Béland-Otis C, Tremblaya A, Castrob MC, Hallb CM, Marcilc JS, Lavoiec JY, Lapointea R (2011) Fossil brines preserved in the St-Lawrence lowlands, Quebec, Canada as revealed by their chemistry and noble gas isotopes. Geochim Cosmochim Acta 75(15):4228–4243CrossRef

Pu JB (2013) Hydrogen and oxygen isotope geochemistry of Karst groundwater in Chongqing (in Chinese). Acta Geosci Sin 34(6):713–722

Rajmohan N, Elango L (2004) Identification and evolution of hydrogeochemical processes in the groundwater environment in an area of the Palar and Cheyyar River basins, southern India. Environ Geol 46(1):47–61

Reynerio Fagundo-Castillo J, Jose Carrillo-Rivera J, Antigueredad-Auzmendi I, Gonzalez-Hernandez P, Pelaez-Diaz R, Hernandez-Diaz R, Caceres-Govea D, Ramon Hernandez-Santana J, Suarez-Munoz M, Melian-Rodriguez C, Rodriguez-Pina M (2008) Chemical and geological control of spring water in eastern Guaniguanico mountain range, Pinar del Rìo, Cuba. Environ Geol 55(2):247–267. https://doi.org/10.1007/s00254-007-1000-7 CrossRef

Richter BC, Kreitler CW (1986) Geochemistry of salt-water beneath the rolling plains, north-central Texas. Ground Water 24(6):735–742CrossRef

Sanders LL (1991) Geochemistry of formation waters from the lower Silurian Clinton formation (Albion sandstone), eastern Ohio. Am Assoc Pet Geol Bull 75(10):1593–1608

Schelkes K, Vogel P, Klinge H (2001) Density-dependent groundwater movement in sediments overlying salt domes: the Gorleben site example. Phys Chem Earth Part B 26(4):361–365CrossRef

Smerdon BD, Allen DM, Grasby SE, Berg MA (2009) An approach for predicting groundwater recharge in mountainous watersheds. J Hydrol 365(3–4):156–172CrossRef

Toth DJ, Katz BG (2006) Mixing of shallow and deep groundwater as indicated by the chemistry and age of karstic springs. Hydrogeol J 14(6):1060–1080CrossRef

Uma KO (1998) The brine fields of the Benue trough, Nigeria: a comparative study of geomorphic, tectonic and hydrochemical properties. J Afr Earth Sci 26(2):261–275CrossRef

Vengosh A, Chivas AR, Starinsky A, Kolodny Y, Baozhen Z, Pengxi Z (1995) Chemical and boron isotope compositions of nonmarine brine from the Qaidam Basin, Qinghai, China. Chem Geol 120(1–2):135–154CrossRef

Walter LM, Stueber AM, Huston TJ (1990) Br-Cl-Na systematics in Illinois Basin fluids: constraints on fluid origin and evolution. Geology 18(4):315–318CrossRef

Wang GW, Li PP, Hao F, Zou HY, Yu XY (2015) Origin of dolomite in the third member of Feixianguan formation (lower Triassic) in the Jiannan area, Sichuan Basin, China. Mar Petrol Geol 63:127–141CrossRef

Wang SL, Zheng MP (2014) Cambrian salt-forming environment in northeastern Sichuan Basin and its significance for finding potash (in Chinese). Sci Technol Rev 32(35):41–49

Worden RH (1996) Controls on halogen concentrations in sedimentary formation waters. Mineral Mag 60(2):259–274. https://doi.org/10.1180/minmag.1996.060.399.02 CrossRef

Worden RH (2014) Controls on halogen concentrations in sedimentary formation waters. Mineral Mag 60(2):259–274

Yin LH, Hou GC, Su XS, Wang D, Dong JQ, Hao YH, Wang XY (2011) Isotopes (δD and δ¹⁸O) in precipitation, groundwater and surface water in the Ordos plateau, China: implications with respect to groundwater recharge and circulation. Hydrogeol J 19(2):429–443CrossRef

Yuan R, Song X, Zhang Y, Han D, Wang S, Tang C (2011) Using major ions and stable isotopes to characterize recharge regime of a fault-influenced aquifer in Beiyishui River watershed, North China plain. J Hydrol 405(3):512–521CrossRef

Yue G (1998) Tectonic characteristics and tectonic evolution of Dabashan orogenic belt and its foreland basin (in Chinese). J Mineral Petrol Sci 18:8–15

Zang HF, Zheng XQ, Qin ZD, Jia ZX (2015) A study of the characteristics of karst groundwater circulation based on multi-isotope approach in the Liulin spring area, North China. Isot Environ Health Stud 51(2):271–284CrossRef

Zarei M, Raeisi E, Merkel BJ, Kummer NA (2013) Identifying sources of salinization using hydrochemical and isotopic techniques, Konarsiah, Iran. Environ Earth Sci 70(2):587–604CrossRef

Zhang P (2011) The investigation and assessment of the main mineral resource in Kaixian of Chongqing (in Chinese). MSc Thesis, Liaoning Technical University, Liaoning, China

Zhou X, Li CJ (1992) Hydrogeochemistry of deep formation brines in the central Sichuan Basin, China. J Hydrol 138(1–2):1–15CrossRef

Zhou X, Li CJ, Ju XM, Du Q, Tong LH (1997) Origin of subsurface brines in the Sichuan Basin. Ground Water 35(1):53–58CrossRef

Zhou X, Cao Q, Li SP, Wang LD, Huang X, Zhang YS, Yin F (2014) Formation of the Ningchang salt spring in Wuxi country of Chongqing (in Chinese). Quat Sci 35(5):1036–1044

Zhou X, Jiang C, Zhao J, Cao Q, Han J, Wang X (2015) Occurrence and resource evaluation of the subsurface high-K-brines in the Pingluoba brine-bearing structure in western Sichuan Basin. Environ Earth Sci 73(12):8565–8574CrossRef

Zhou X, Jin X, Liang S, Shen Y, Zhang H (2017) Special Topics on Groundwater Sciences (Second Edition). Geological Publishing House, Beijing, pp 88–110. (in Chinese)

Titel: Hydrogeochemical characteristics and sources of salinity of the springs near Wenquanzhen in the eastern Sichuan Basin, China
verfasst von: Juan Guo
Xun Zhou
Lidong Wang
Yuqi Zhang
Xiaowei Shen
Haiyan Zhou
Shen Ye
Bin Fang
Publikationsdatum: 04.12.2017
Verlag: Springer Berlin Heidelberg
Erschienen in: Hydrogeology Journal / Ausgabe 4/2018
Print ISSN: 1431-2174
Elektronische ISSN: 1435-0157
DOI: https://doi.org/10.1007/s10040-017-1692-z

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