Abstract
Geothermal resources are practical and competitive clean-energy alternatives to fossil fuels, and study on the recharge sources of geothermal water supports its sustainable exploitation. In order to provide evidence on the recharge source of water and circulation dynamics of the Tangshan Geothermal System (TGS) near Nanjing (China), a comprehensive investigation was carried out using multiple chemical and isotopic tracers (δ2H, δ18O, δ34S, 87Sr/86Sr, δ13C, 14C and 3H). The results confirm that a local (rather than regional) recharge source feeds the system from the exposed Cambrian and Ordovician carbonate rocks area on the upper part of Tangshan Mountain. The reservoir temperature up to 87 °C, obtained using empirical as well as theoretical chemical geothermometers, requires a groundwater circulation depth of around 2.5 km. The temperature of the geothermal water is lowered during upwelling as a consequence of mixing with shallow cold water up to a 63% dilution. The corrected 14C age shows that the geothermal water travels at a very slow pace (millennial scale) and has a low circulation rate, allowing sufficient time for the water to become heated in the system. This study has provided key information on the genesis of TGS and the results are instructive to the effective management of the geothermal resources. Further confirmation and even prediction associated with the sustainability of the system could be achieved through continuous monitoring and modeling of the responses of the karstic geothermal reservoir to hot-water mining.
Résumé
Les ressources géothermales sont des énergies alternatives propres pratiques et compétitives face aux combustibles fossiles, et l’étude de l’origine de la recharge des eaux géothermales permettent leur exploitation durable. Afin de démontrer les origines de la recharge des eaux et leur dynamique de circulation dans le Système Géothermal du Tangshan (TGS) près de Nanjing (Chine), une étude complète a été mise en œuvre, utilisant un cortège de traceurs chimiques et isotopiques (δ2H, δ18O, δ34S, 87Sr/86Sr, δ13C, 14C and 3H). Les résultats confirment que la recharge du système est. locale (plus que régionale) et provient d’affleurements de roches carbonatées du Cambrien et de l’Ordovicien, dans la partie haute des montagnes du Tangshan. La température du réservoir jusqu’à 87 °C, obtenue en utilisant des géothermomètres chimiques empiriques aussi bien que théoriques, nécessite une circulation des eaux souterraines à une profondeur autour de 2.5 km. La température des eaux géothermales diminue lors de la remontée, en raison d’un mélange avec de l’eau froide superficielle, pouvant atteindre jusqu’à 63% de dilution. Les âges corrigés 14C montrent que les eaux géothermales se déplacent à de très faibles vitesses (d’échelle millénaire) et ont de faibles taux de circulation, leur permettant d’avoir suffisamment de temps pour se réchauffer dans le système. L’étude a fourni des informations clés sur la formation du TGS et les résultats sont instructifs pour la gestion efficace des ressources géothermales. Un suivi en continu et une modélisation de la réponse de l’aquifère karstique géothermal, à l’exploitation de l’eau chaude, permettraient de confirmer ces résultats et de prédire la pérennité du système.
Resumen
Los recursos geotérmicos son alternativas prácticas y competitivas de energía limpia a los combustibles fósiles, y el estudio de las fuentes de recarga de agua geotérmica respalda su explotación sostenible. Con el fin de proporcionar evidencias de la fuente de recarga de agua y de la dinámica de la circulación del Sistema Geotérmico de Tangshan (TGS) cerca de Nanjing (China), se realizó una investigación exhaustiva utilizando trazadores isotópicos (δ2H, δ18O, δ34S, 87Sr/86Sr, δ13C, 14C y 3H) y múltiples elementos químicos. Los resultados confirman que una fuente de recarga local (en lugar de regional) alimenta al sistema del área expuesta con rocas de carbonato del Cámbrico y Ordovícico en la parte superior de la Tangshan Mountain. La temperatura del depósito de hasta 87 °C, obtenida utilizando geotermómetros químicos tanto empíricos como teóricos, requiere una profundidad de circulación del agua subterránea de alrededor de 2.5 km. La temperatura del agua geotérmica se reduce durante la surgencia como consecuencia de la mezcla con agua fría somera hasta una dilución del 63%. La edad corregida de 14C muestra que el agua geotérmica viaja a un ritmo muy lento (escala milenaria) y tiene una baja tasa de circulación, permitiendo un tiempo suficiente para que el agua se caliente en el sistema. Este estudio ha proporcionado información clave sobre la génesis del TGS y los resultados son instructivos para la gestión eficaz de los recursos geotérmicos. Se podría lograr una confirmación e incluso una predicción adicional asociadas con la sostenibilidad del sistema a través del monitoreo y modelado continuo de las respuestas del reservorio geotérmico cárstico a la extracción de agua caliente.
摘要
地热资源是一种可以代替化石燃料且具有很强实用性和竞争力的清洁能源,对地热水补给来源的研究可以为其可持续开发提供支撑。为了提供位于南京(中国)附近的汤山地热系统(TGS)地热水补给来源和循环动力学的证据,利用多种水化学和同位素示踪剂(δ2H, δ18O, δ34S, 87Sr / 86Sr, δ13C, 14C和3H)对其进行了综合研究。研究结果表明,地热水的补给主要来自当地的(而不是区域性)汤山上部裸露的寒武系和奥陶系碳酸盐岩地区。使用经验和理论化学热力学温标方法预测深部热储温度可以达到87°C,这需要地下水循环深度在2.5公里左右。在上涌过程中地热水的温度降低了,这是因为在上涌过程中与浅层冷水发生了混合, 冷水混合比可以达到63%。经过校正的14C年龄显示,地热水以非常缓慢的速度(千年尺度)流动,并且循环更新速率较低,从而有足够的时间使水在地热系统中被加热。这项研究为TGS的成因提供了关键信息,对于地热资源的有效管理具有重要的指导意义。通过持续监测和模拟岩溶热储对热水开采的响应,可以进一步确认和预测地热系统开发的可持续性。
Resumo
Recursos geotermais são uma alternativa energética limpa prática e limpa aos combustíveis fósseis, e estudos sobre as fontes de recarga da água geotermal alicerça a sua exploração sustentável. Para fornecer evidências sobre a recarga das fontes de água e a dinâmica da circulação no Sistema Geotérmico Tangshan (SGT) próximo a Nanjing (China), uma investigação detalhada foi conduzida utilizando múltiplos traçadores químicos e isotópicos (δ2H, δ18O, δ34S, 87Sr/86Sr, δ13C, 14C e 3H). Os resultados confirmam que uma fonte de recarga local (mais do que a regional) alimenta o sistema a partir das áreas de afloramento de rochas carbonáticas Cambrianas e Ordovicianasna parte superior da Montanha Tangshan. A temperatura do reservatório acima dos 87 °C, obtido usando geotermômetros químicos tanto empíricos quanto teóricos, requer uma circulação das águas subterrâneas a uma profundidade em torno de 2.5 km. A temperatura das águas geotermais é diminuída durante ressurgência como uma consequência da mistura com águas rasas frias a uma diluição de 63%. A datação 14C corrigida mostra que a água geotermal viaja a um passo muito lento (escala milenar) e tem uma baixa taxa de circulação, permitindo tempo suficiente para que a água se torne aquecida no sistema. Esse estudo forneceu informações chave sobre a gênese do SGT e os resultados são instrutivos para uma gestão efetiva dos recursos geotérmicos. Confirmações adicionais e até predições associadas com a sustentabilidade do sistema podem ser alcançadas pelo monitoramento contínuo e modelagem da resposta do reservatório cárstico geotermal à mineração de água quente.
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Introduction
Geothermal resources, consisting of heat, minerals and water, are one of the most practical and competitive clean-energy sources available as a viable alternative to fossil fuels to mitigate global climate change (Kong et al. 2014; Michael et al. 2010; Wang 2009; Wang et al. 2015). The global development of geothermal energy has become more and more rapid since the 1970s (Lund and Boyd 2016) because it is widely distributed, environmentally friendly and economically profitable (Montanari et al. 2017; Yang et al. 2017); however, uncontrolled mining of geothermal water may result in continuous decline of the water table and the reservoir temperature (Duan et al. 2011), which is not sustainable. Sustainable use of geothermal resources is a new challenge for the scientific community (Hähnlein et al. 2013; Mongillo 2010).
Systematic hydrochemical and isotopic studies on geothermal systems are essential tools toward effective exploration and sustainable use of geothermal resources (Guo et al. 2010; Kong et al. 2014; Reinsch et al. 2013). Different aspects of a geothermal/groundwater system can be unveiled with different hydrogeochemical and isotopic methods. Stable δ18O and δ2H isotopes combined with hydrochemistry have been widely used in tracing sources of groundwater and delineating water–rock–gas interaction processes occurring in groundwater systems (Awaleh et al. 2015; Bo et al. 2015; Bozdağ 2016; Chandrajith et al. 2013; Diamond and Harris 2000; Ghomshei and Clark 1993; Guo et al. 2010; Li et al. 2017; Ma et al. 2009; Majumdar et al. 2005; Pang 2011; Wang et al. 2016; Xu et al. 2017). In the past two decades, the Sr isotopic ratio of 87Sr/86Sr has been widely used as a tracer for delineating hydrogeochemical processes, the origin of groundwater and chemical components, and the mixing effect in groundwater systems (Bakari et al. 2013; Barbieri and Morotti 2003; Boschetti et al. 2005; Brenot et al. 2015; Grobe et al. 2000; Guo et al. 2010; Khaska et al. 2015; Wang et al. 2006). The sulfur isotope δ34S in sulfate has been commonly used to trace the origin of sulfate content, groundwater evolution and water–rock interactions occurring in groundwater systems (Al-Charideh 2015; Raidla et al. 2014; Sack and Shama 2014). Groundwater age can be used to evaluate the circulation rate and renewability of groundwater (Huang et al. 2017a, b) and 14C in dissolved inorganic carbon (DIC) has been commonly used for age determination by hydrogeologists (Edmunds et al. 2006; Han et al. 2014; Huang et al. 2017b). While empirical chemical geothermometers including quartz (Fournier 1977), chalcedony (Fournier, 1977), and cation geothermometers (Fournier 1979; Fournier and Truesdel 1973; Fournier and Potter 1979; Giggenbach 1988; Pang et al. 2013) are still used to predict reservoir temperature, it is now quite common that theoretical chemical geothermometers based on a chemical thermodynamic modeling approach are used, which was proposed and improved by Reed and Spycher (1984), Pang and Reed (1998) and Spycher et al. (2013).
In China, geothermal resources are widely distributed, especially the low-medium temperature hydrothermal resources (Lund and Boyd 2016; Wang et al. 1993). Low-medium temperature geothermal systems hosted in carbonate rocks are some of the most promising and unknown geothermal systems (Kong et al. 2015; Montanari et al. 2017; Pang et al. 2015). Tangshan area is one of the most famous “hot spring towns” in China (Zhao and Zhu 1998) with a low-medium temperature convective geothermal system developed in carbonate rocks. With the rapid development of tourism, the demand for geothermal resources has increased significantly (Zhao and Zhu 1998). During the past two decades, rapid decline of the water level has occurred in many geothermal wells, with all historical hot springs having vanished and some geothermal wells dried up (Zhao and Zhu 1998). In order to achieve sustainable use of geothermal water in Tangshan, it is necessary to fill the knowledge gap on Tangshan Geothermal System (TGS); however, to the best knowledge of the authors, limited hydrogeochemical and isotopic studies on TGS have been carried out. The previous studies have revealed the geological background and tectonic framework of the system. They speculated on the genesis of TGS based on geological information (Li et al. 2010; Luan and Qiu 1998; Zhao and Zhu 1998) with limited analyses on hydrochemistry and stable isotopes (δ2H and δ18O; Zou et al. 2015).
In order to achieve a comprehensive understanding on TGS, a multi-tracer approach involving hydrochemistry and isotopes (δ2H, δ18O, δ34S, 87Sr/86Sr, δ13C, 14C, 3H) was implemented, aiming at solving a few key scientific issues: (1) Does the geothermal system get water recharge from a local source or a remote source? (2) What is the groundwater circulation rate and what are the implications of that on the sustainable use of geothermal water?
Study area
TGS is located in the eastern suburb of city of Nanjing, Jiangsu Province, which is approximately 25 km (Fig. 1a) from the downtown of Nanjing. Tangshan area features a subtropical monsoon climate with an annual average temperature of 15.4 °C and annual average precipitation of 1,060 mm. The main surface-water system here is Tangshui River and Tangshan reservoir to the east of Tangshan (Fig. 1b). Tangshan Mountain is approximately east–west trending, and about 5 km long and 3 km wide. The main geomorphologies are low mountains and hills with elevation varying from 150 to 300 m a.s.l, and the peak is Tuanzijian Mountain (Fig. 1b) with an elevation of about 300 m a.s.l. in the middle of Tangshan (Zou et al. 2015).
Sedimentary strata developed in the region are almost continuous from Cambrian to Cretaceous periods; however, the main strata developed in Tangshan are dolomite of the Cambrian system, limestone of the Ordovician system, sandstone and shale of the Silurian system, and sandstone and mudstone of the Cretaceous system, with Devonian to Jurassic systems missing (Zhao and Zhu 1998). The Cambrian and Ordovician systems are exposed over Tangshan and form the Tangshan body. The Silurian system is mainly represented in the west and north of Tangshan, while the Cretaceous system is mainly distributed in the east and south of Tangshan (Fig. 1b). Quaternary formations are widely distributed in the piedmont area and valley with thickness varying from 2 to 40 m. Quartz diorite porphyry of Yanshan age is mainly presented in the north of Tangshan (Zou et al. 2015).
Tectonically, Tangshan is located in the west part of Ningzhen uplift structure bordered by Tangshan-Dongchangjie fault to the south of Tangshan (Luan and Qiu 1998). Locally, Tangshan is located in the center of the Tangshan-Lunshan anticlinorium. The core of the Tangshan anticline is made of Cambrian and Ordovician systems, while the flanks are composed of the Silurian system. Three groups of fault structures, NE, NW and EW faults, developed in Tangshan, which are mainly distributed in the east, middle and south of Tangshan. The east part of Tangshan anticline was cut by NW and NE faults, resulting in the falling of formations in the east (Fig. 1c).
The aquifers developed here can be classified into two categories: porous formation in unconsolidated Quaternary sediments, and fractured bedrock (karstic and clastic rocks). The Quaternary formations are low in permeability. Karstic groundwater, including cold and thermal groundwaters, is distributed in the carbonate rock formations of Cambrian and Ordovician systems with high permeability. The cold karstic groundwater is mainly present in the middle of Tangshan Mountain, while thermal karstic groundwater is in the east and west of Tangshan. Fractured aquifers in clastic rocks mainly appear in the sandstone and shale of the Silurian and Cretaceous systems, in which fractures are less developed and permeability is much lower, and can be regarded as aquitards. The water table in Tangshan has significantly declined (up to 10 m) during recent years due to increased use of geothermal resources. In this study, thermal water samples were collected from Cambrian and Ordovician aquifers and cold shallow samples mainly from Quaternary, Silurian and Cretaceous aquifers with three from carbonate rock aquifers.
Tangshan Geothermal System (TGS) is a low-medium temperature convective geothermal system (Luan and Qiu 1998; Wang et al. 1993). The regional terrestrial heat flow is 54–58 mW/m2, and the average geothermal gradient is 26–28 °C/km in the depth range of a few hundred meters. The wellhead temperature is about 50–65 °C in the eastern and 30–39 °C in the western ends of the mountain. The geothermal reservoirs are composed of carbonate rocks of Cambrian and Ordovician systems. The caprock, mainly distributed in the piedmont area of Tangshan, mainly consisted of formations of Quaternary, Silurian and Cretaceous systems (Li et al. 2010; Zhao and Zhu 1998). The locally developed faults and other structures provide good circulation channels for geothermal water.
Materials and methods
Collection of samples
A sampling campaign was implemented in April 2016, in which a total of 46 water samples were collected including 2 samples from Tangshui River, 5 samples from Tangshan reservoir, 32 samples from drinking water wells and 7 samples from geothermal wells. The groundwater sampling locations are shown in Fig. 1b. All samples for hydrochemical analyses were filtered with a 0.45-μm membrane before bottling. Samples for cation and trace elements analysis were acidified with ultra-purified HNO3 to adjust the sample to pH < 2. Filtered 60 ml of water were collected into HDPE vials for anion analyses. A total of 20 ml of filtered water was collected into screw capped HDPE vials for stable δ18O and δ2H analyses, whereas 1,000 ml of unfiltered water was collected into screw capped HDPE bottles for δ13C and 14C analyses, 200 ml of water for 87Sr/86Sr analyses, and 1,000 ml of water for δ34S analyses.
Analytical methods
Physical and chemical parameters such as pH, total dissolved solids (TDS), temperature, electrical conductivity, and redox potential (Eh), were measured on site using a multi-parameter device, the Hach HQ40D. HCO3 was analyzed on site by a digital titrator (Model 16900, Hach) with 0.8 N H2SO4 using bromocresol green-methyl red indicator. Other chemical and isotopic analyses were performed in laboratories within about 1 week after collection. The main anions (F, Cl, and SO4, with detection limit of 0.1 mg/L) and cations were determined using a Dionex-500 ion chromatograph (detection limit is 0.1 mg/L) in the Water Isotope and Water–Rock Interaction Laboratory at the Institute of Geology and Geophysics, Chinese Academy of Sciences (IGG-CAS). Trace elements (Sr, Si, etc.) were measured by ICP-MS (detection limit is 0.1 μg/L) in the Analytical Laboratory of the Beijing Research Institute of Uranium Geology (BRIUG). Stable isotopes (δ18O, δ2H) were analyzed in the Water Isotope and Water–Rock Interaction Laboratory at IGG-CAS by the laser absorption water isotope analyzer Picarro L1102-i (the precision of the δ18O and δ2H values were ±0.1 and ±0.5‰, respectively). δ13C and 14C in groundwater samples were measured at Beta Analytic in the USA using accelerator mass spectrometry (AMS). The analytical precision was ±0.1‰ for δ13C and ±0.1 pmC for 14C. 87Sr/86Sr of groundwater samples was measured in the Analytical Laboratory of BRIUG by Phoenix TIMS stable isotope mass spectrometry. The δ34S in dissolved SO42− was measured in the stable isotopes laboratory of IGG-CAS by MAT 253 stable isotope mass spectrometry. The results of water chemistry and isotopic compositions of water samples are shown in Table S1 of the electronic supplementary material (ESM). The software PHQEERC 3.0 and the llnl.dat dataset (Parkhurst and Appelo 2013) developed by the United States Geological Survey (USGS) was applied to calculate the mineral saturation index (SI).
Results
Water chemistry
The results of water chemistry analyses are given in Table S1 of the ESM. Based on the properties and chemical composition, the water samples can be divided into three categories: cold surface water (CSW) (including reservoir and river water), cold shallow groundwater (CSG), and geothermal groundwater (GG). The charge balances of all samples are within ±5% (Table S1 of the ESM).
A Piper plot of all water samples is shown in Fig. 2. For CSW, the pH varies from 8.6 to 9.0. The dominant anions are SO4 and HCO3 with SO4 ranging from 60.1 to 154.7 mg/L and HCO3 from 84.4 to 173.3 mg/L. The dominant cation is Ca with a concentration range of 62.5 to 80.0 mg/L. The water type is mainly HCO3-Ca/SO4·HCO3-Ca (Fig. 2; Table S1 of the ESM) with TDS ranging from 291.0 to 352.0 mg/L (Table S1 of the ESM).
The CSG samples were mainly taken from Quaternary, Silurian and Cretaceous aquifers. The pH varies from 6.9 to 10.8. The dominant cation and anion are Ca and HCO3 with the concentration range of 52.1–151.1 mg/L and 7.3–389.0 mg/L for Ca and HCO3, respectively. The water type is mainly HCO3-Ca/ HCO3·SO4-Ca (Fig. 2; Table S1 of the ESM) with TDS ranging from 193.0 to 819.0 mg/L (Table S1 of the ESM). The concentration range of Sr is from 143.0 to 846.0 mg/L.
The GG samples were mainly taken from Ordovician and Cambrian carbonate aquifers. The pH varies from 7.1 to 8.0. The concentrations of Sr and SO4 are the highest in GG samples, with the content range of 6,921.0 to 10,488.0 μg/L and 319.8 to 1,012.9 mg/L for Sr and SO4, respectively, compared to CSW and CSG samples. The dominant cation is Ca with concentration varying from 185.2 to 380.4 mg/L. The main water type is SO4-Ca (Fig. 2; Table S1 of the ESM) except sample 16D04 (SO4·HCO3-Ca, which may be affected by mixing with CSG) with TDS ranging from 713.0 to 1,580.0 mg/L (Table S1 of the ESM). The wellhead temperatures measured on site vary from 34.1 to 65.3 °C.
Isotopic compositions
The isotopic results are shown in Table S1 of the ESM, which indicates that δ2H and δ18O in CSW are the most enriched, with δ2H ranging from −24.8 to −34.5 ‰ and δ18O from −3.8 to −5.1 ‰, followed by CSG with δ2H ranging from −18.6 to −49.1 ‰ and δ18O from −3.9 to −7.7 ‰ (Fig. 3). δ2H and δ18O in GG samples are the most depleted with δ2H ranging from −49.1 to −55.8 ‰ and δ18O from −7.5 to −8.6 ‰ (Fig. 3), which is probably related to higher recharge elevation.
87Sr/86Sr analyses of seven GG samples and 17 CSG samples were conducted in this study (Table S1 of the ESM). The value of 87Sr/86Sr in GG samples is low with a narrow range of 0.709136 to 0.709210, while the value in CSG samples is relatively high with a wide range of 0.709514 to 0.713183 (Fig. 4a), which indicates different water–rock reactions between them.
δ34S analyses of seven GG samples and 11 CSG samples were conducted in this study (Table S1 of the ESM). The δ34S in GG samples is enriched, varying from 28.165 to 33.695 ‰, while that in CSG samples is relatively depleted with a range of 1.165 to 22.321 ‰ (Fig. 5). Meanwhile, the δ34S value of most GG samples (85.7%) is around 30 ‰, while that of most (81.8%) CSG samples is below 10‰ (Fig. 5). δ34S is controlled by different SO4 sources.
A total of seven 14C, δ13C, and tritium (3H) samples of GG were measured (Table S1 of the ESM). The 14C activities in dissolved inorganic carbon (DIC) of GG samples are relatively low with values varying from 21.4 to 76.9 pmC (Fig. 6). The δ13C in DIC of GG samples is relatively enriched with values varying from −13.2 to −9.1 ‰ (Fig. 6). 3H was not detected in GG samples (therefore not shown in Table S1 of the ESM).
Discussion
Water–rock reactions
Water–rock reactions are important geochemical processes in geothermal water and shape the characteristics of water chemistry. The linear relationship between mNa and mCl (as mmol/L) is shown in Fig. 7a. All the GG samples plot near the line of mNa:mCl = 1:1, suggesting that Na and Cl were mainly derived from NaCl dissolution (Huang et al. 2017a); however, some CSG samples lie below the line of mNa:mCl = 1:1, indicating that apart from NaCl dissolution, dissolution of albite in formations (Eq. 1) might contribute to the additional Na (Huang et al. 2017a):
The relationship between m(Ca + Mg) and mHCO3 (as mmol/L) is given in Fig. 7b, between mCa and mMg is given in Fig. 7c, and mCa and mSO4 is given in Fig. 7d (as meq/L). All GG samples lie above the line of m(Ca + Mg):mHCO3 = 1:1, while the CSG samples plot on or below the line (Fig. 7b). Although both of GG and CSG samples lie above the line of mCa:mMg = 1:1, the ratios of mCa to mMg are much greater in GG samples (Fig. 7c). All GG samples plot near or below the line of mCa:mSO4 = 1:1, while most of CSG samples lie above the line (Fig. 7d). The different characteristics of chemical compositions suggest different water–rock interaction processes and weak connections between CSG and deep GG. If only dissolution of calcite and dolomite (Eqs. 3 and 4) occurred in the geothermal reservoir, the ratio of m(Ca + Mg) to mHCO3 should be <1 (Huang et al. 2017a, b), which is not the case in this study. The high content of Ca and SO4 and the ratio of mCa to mSO4 close to 1 suggests that, except for carbonate dissolution, anhydrite (embedded in carbonate rock) dissolution (Eq. 2) also occurred (Ma et al. 2011) and it dominates the water–rock interaction processes in the geothermal reservoir, which is also demonstrated by mineral saturation indices (SI) and Sr and S isotopes (see the following discussion).
The mineral SI of GG samples are shown in Table 1. The SI of calcite and dolomite is greater than 0 and anhydrite (gypsum) is less than 0, suggesting precipitation tendency for carbonate minerals and dissolution tendency for gypsum, which is consistent with the hydrochemical results. The significant dissolution of gypsum may lead to precipitation of carbonate minerals to some extent, which consequently results in some GG samples lying below the line of mCa:mSO4 = 1:1 (Fig. 7d; Ma et al. 2011). The significant negative values of SI of albite indicate that albite dissolution is probably much limited in the geothermal reservoir, which is in agreement with the hydrochemical results.
Dissolved Sr in groundwater is generally derived from geological components through water–rock interactions and cation exchange reactions (Bakari et al. 2013). The 87Sr/86Sr ratio is a good tracer of the rock type that has interacted with groundwater, and when combined with chemical compositions it might be useful for identifying the potential water–rock interaction processes (Guo et al. 2010; Khaska et al. 2015; Wang et al. 2006). The 87Sr/86Sr ratios of GG samples are low (0.709136 ~ 0.709210, Fig. 4a) showing a typical carbonate or evaporite (gypsum, anhydrite) weathering source (Négrel and Roy 1998), while those in CSG samples are relatively high (0.709514 ~ 0.713183) showing a typical silicate weathering source (Faure 1986; Négrel and Roy 1998), which is consistent with the respective lithology of aquifers. The GG samples have low 87Sr/86Sr ratio and high Sr, Ca and SO4 concentrations, while CSG samples have high 87Sr/86Sr ratio and low Sr, Ca and SO4 concentrations (Fig. 4), indicating weak hydraulic connections between CSG and deep GG. Both Sr-SO4 (Fig. 8a) and Sr-Ca (Fig. 8b) show a positive correlation. The 87Sr/86Sr ratio combined with hydrochemistry demonstrates that the high Sr content was mainly derived from carbonate and gypsum dissolution in GG. In other words, carbonate and gypsum dissolution are the main water–rock interactions processes.
The GG samples have high SO4 content. δ34S in dissolved SO4 has been extensively used as a tracer for determining the source of SO4 and the relevant geochemical processes (Raidla et al. 2014; Sack and Shama 2014). The GG samples are enriched in δ34S (28.165 ~ 33.695 ‰), and the δ34S values stay around 30 ‰ with increasing SO4 concentration (Fig. 5), which suggests a typical sulfate (gypsum and anhydrite) dissolution source of SO4 (Raidla et al. 2014). The GG samples have enriched δ34S and high SO4 concentration, while the CSG samples have relatively depleted δ34S and low SO4 concentration, demonstrating weak hydraulic connections between CSG and deep GG.
Reservoir temperature calculation
In case of no drilling temperature measurement, fluid geothermometry can be used to predict reservoir temperature. Cation geothermometry, theoretical chemical geothermometry and silica (SiO2) geothermometry were applied in this study to comprehensively evaluate the reservoir temperature.
Cation geothermometry
The results of cation geothermometry are shown in Table 2. The calculated temperatures are either too high for this study area or lower than wellhead temperature, which is not reasonable. The Giggenbach Na/1000-K/100-SQR (Mg) ternary plot (Giggenbach 1988) is a classic method to check the equilibrium state of geothermal water with relevant minerals and can also be used to predict reservoir temperature. The Giggenbach plot (not shown) shows that the GG samples lie in the immature water area, also indicating that cation geothermometry is unsuitable in this case.
SiO2 geothermometry
This method is based on the dissolution equilibrium of SiO2 in geothermal water to predict the reservoir temperature. The calculated results of different SiO2 geothermometries are shown in Table 3. Only the chalcedony geothermometry gives a reasonable temperature and the calculated temperatures of 16D05 and 16D07 are close to that of theoretical chemical geothermometry. The calculated temperature of 16D04 is relatively low and probably is affected by mixing with CSG. The calculated temperatures of other methods are lower than the wellhead temperatures or even negative values, and therefore not suitable.
Theoretical chemical geothermometry
This method is used to verify whether the geothermal water in the reservoir has reached equilibrium with relevant mineral assemblages in the host rock (Pang and Reed 1998; Reed and Spycher 1984) and provides the reservoir temperature if equilibrium is established. The variations of the SI with increasing temperature were calculated using SOLVEQ-XPT code (Reed et al. 2012). The two samples with the highest wellhead temperature, 16D05 and 16D07, were taken as examples of how to apply this method. The forced equilibrium of calcite was adopted to correct CO2 degassing and the forced equilibrium of microcline was conducted to correct possible aluminum concentration error (Pang and Reed 1998). The possible mixing and dilution effects were also corrected (Pang and Reed 1998). The calculation results are shown in Fig. 9, which gives the temperature of 73–80 °C for 16D05 and 75–80 °C for 16D07.
From the preceding discussion, the calculated temperatures of chalcedony geothermometry are most reasonable and close to those of theoretical chemical geothermometry, and therefore regarded as the reservoir temperature in this study. The reservoir temperature in the west of Tangshan is about 51 °C (16D06), while that in the east of Tangshan is 74–87 °C, with an average of 80 °C and relatively high. The difference between the reservoir temperatures in the east and west of Tangshan is probably related to the depth of the geothermal reservoir, as the geothermal reservoir in the east is deeper due to the effect of the fault structure.
Groundwater circulation depth
The groundwater circulation depth can be calculated using the following equation (Li and Li 2010):
where D is circulation depth (km); T is reservoir temperature (°C); T0 is the temperature of the constant temperature zone (°C); G is the geothermal gradient (°C/km). The groundwater circulation depth of 2.3–2.5 km was obtained with the average reservoir temperature of 80 °C assumed for T, annual average temperature of 15.4 °C for T0 and average geothermal gradient of 26–28 °C/km for G.
Recharge source of geothermal water
H and O stable isotopes (δ2H and δ18O) are good tracers for determining the recharge of groundwater as they carry the information of water itself. The relationship between δ2H and δ18O is shown in Fig. 3. The local meteoric water line (LMWL, δ2H = 8.3δ18O + 16.3 ‰) was established with isotopic data from the Nanjing monitoring station of the Global Network of Isotopes in Precipitation (GNIP; IAEA/WMO 2017). The isotopic precipitation weighted average of the local meteoric water is δ18O = −7.7 ‰ and δ2H = −49.2 ‰. The CSW samples mainly originated from local precipitation according to field investigations. The CSW samples are enriched in 2H and 18O and lie in the lower right region of the LMWL (Fig. 3), indicating the evaporation effect (Clark and Fritz 1997). The local evaporation line (LEL) was established using a linear regression algorithm. The value of the intersection of LMWL and LEL is δ18O = −7.8 and δ2H = −48.4 ‰, which is very close to the isotopic precipitation weighted average of local meteoric water, suggesting the rationality of the established LMWL to some extent.
Although both the GG and CSG samples lie on or near the LMWL (Fig. 3), they are completely separated (except for 16D04) on Fig. 3 with isotopes in CSG samples being more enriched. This suggests that both GG and CSG were recharged by local precipitation, but the hydraulic connections between them are very limited. A remarkable oxygen isotope shift in Tangshan geothermal waters was not observed probably due to low reservoir temperature (Pang 2011), proving the reasonability of the aforementioned reservoir temperature calculation. The depleted isotopic composition in GG samples may be related to high recharge elevation.
The isotopic elevation effect of δ18O can be used to evaluate groundwater recharge elevation (Clark and Fritz 1997):
where hR is the recharge elevation, δG is the isotopic value of groundwater samples, δP is the isotopic value of local precipitation, hG is the sampling point elevation of groundwater and K is the elevation gradient of δ18O. In this study, the isotopic precipitation weighted average of δ18O = −7.7 ‰ was assumed for δP, the average elevation gradient of the low latitude zone in southern China of −0.3 ‰/100 m was assumed for K (Wang and Wang 2011). The calculation results of recharge elevation of GG are shown in Table 4. The recharge elevation varies from 137.5 to 301.9 m a.s.l., which is close to the elevation range of Tangshan. The calculation result of 16D04 is a negative value, which is probably due to significant mixing with CSG during upwelling.
Both the major hydrochemical compositions (Na, Ca, Mg, Sr, SO4, HCO3, Cl) and isotopic compositions (δ2H, δ18O, δ34S, 87Sr/86Sr) are significantly different between GG and CSG, indicating weak hydraulic connections between them. Additionally, the permeability of the regionally distributed sandstone and shale of Silurian and Cretaceous systems overlying the geothermal reservoir in Tangshan is much lower (regarded as aquitards). It is hard for precipitation to penetrate through them to recharge the geothermal reservoir. On the other hand, the H and O stable isotopes suggest that the GG in Tangshan was recharged by local precipitation and the recharge elevation is close to the elevation range of Tangshan. Both the hydrochemical and isotopic compositions demonstrated that the GG in Tangshan mainly flowed through carbonate formation and reacted with carbonate minerals and anhydrite (gypsum). Furthermore, the body of Tangshan is distributed with exposed Cambrian and Ordovician carbonate rock with lots of NE and NW fault tectonics developed, which is conducive for receiving precipitation recharge to the geothermal reservoir. From the aforementioned text, the body of Tangshan distributed with exposed Cambrian and Ordovician carbonate rock is the most possible recharge zone for Tangshan GG. The precipitation penetrated through the carbonate formation of Cambrian and Ordovician systems to deeper layers and was heated up by the geothermal reservoir. The heated water then circulated upward along tectonic fissure to surface due to encountering the low permeability of sandstone and shale of the Silurian and Cretaceous strata overlying the geothermal reservoir, and mixed with cold shallow karstic water during upwelling.
Mixing model based on Sr and 87Sr/86Sr
Mixing with shallow cold groundwater often occurs for geothermal water during upwelling (Guo et al. 2010, Guo et al. 2017). Both the hydrochemical compositions (Figs. 7b–d and 8) and isotopic compositions (Figs. 4 and 5) suggest the occurrence of mixing between GG and cold groundwater especially for sample 16D04. In order to validate the mixing process, a binary mixing model between two endmembers using Sr and 87Sr/86Sr (Bakari et al. 2013; Faure 1986; Négrel et al. 2004) was considered:
where (87Sr/86Sr)m is the measured isotopic ratio, [Sr]m is the measured Sr concentration in the mixture, (87Sr/86Sr)1 and (87Sr/86Sr)2 represent the isotopic ratios of the first and second endmembers, respectively, [Sr]1 and [Sr]2 the Sr concentrations of the two endmembers, respectively, and f is the fraction of endmember 1.
Since the hydraulic connections between deep GG in karstic aquifers and shallow groundwater in fractured aquifers of clastic rocks are weak, the mixing between deep GG and cold shallow karstic groundwater during upwelling is the most possible. The 87Sr/86Sr values of samples 16D08, 16D28 and 16D47 are below 0.710 and closest to that of GG among all the CSG samples, which therefore are considered as cold shallow karstic groundwater. These three samples lie approximatively along a mixing line with GG samples (Fig. 4a); therefore, sample 16D28 (87Sr/86Sr = 0.709563, Sr = 846.0 μg/L), closest to GG samples (Fig. 4a), was assumed for the cold water endmember. The three samples of 16D03/16D05/16D07 with the highest wellhead temperature have similar lowest 87Sr/86Sr and highest Sr content. Here the average (87Sr/86Sr = 0.709170, Sr = 9914.0 μg/L) of the three samples was assumed for the value of the geothermal water endmember. The calculation results are shown in Table 5. Sample 16D04 has the highest mixing fraction (63.1%) of cold water proving the speculation previously discussed, deduced from hydrochemical and isotopic results. Other samples have the low mixing fraction (around 30%) of cold water.
14C age of geothermal water
This study used 14C to evaluate the age of GG in Tangshan. The 14C age (t) of groundwater was determined by the following equation:
where at is the measured 14C content in groundwater samples, and a0 is the initial 14C content. However, the dissolution of carbonate minerals can dilute the true initial 14C activity of DIC in groundwater. The relationship between 14C and δ13C of GG samples is shown in Fig. 6. The 14C value shows a decreasing trend with increasing δ13C, indicating the dilution effect of carbonate minerals dissolution. There are many models that can be used to correct the dilution effect. In this study, Tamers (1975), Fontes and Garnier (1979), Evans et al. (1979), Eichinger (1981), Pearson model (Pearson 1965) and Pearson model considering the isotopic fractionation between soil CO2 and DIC (abbreviated as Pearson model No. 2; Clark and Frintz 1997) were adopted to correct the 14C age. The initial 14C activity of 100 pmC, δ13C of carbonate minerals of 0 ‰ and δ13C of soil CO2 of −23 ‰ were assumed during the correction.
The age evaluation results are shown in Table 6. The results of Tamers, Fontes and Garnier, Evans, Eichinger and Pearson models include some negative age values which are not reasonable. Only the Pearson model No. 2 gives the relatively reasonable results which are considered as the corrected 14C age of GG in Tangshan. Although the corrected absolute age may deviate from the real age to some extent, it is believed to be more accurate than the uncorrected age and can indicate the age level of groundwater (Huang and Pang 2011). The age of GG in the east of Tangshan is relatively old (944–9,155 years) compared to that in the west of Tangshan (16D06 = 1,777 years). The lowest age of sample 16D04 probably resulted from mixing with shallow groundwater as previously discussed. In summary, the age of GG in Tangshan is on the level of millennial scale, which is consistent with the fact that GG samples are tritium-free.
Implications for sustainable use of geothermal water
Groundwater renewability refers to the ability to replace the groundwater extracted from the aquifer through recharge, naturally or artificially (Wang et al. 2011; Huang et al. 2017b). When geothermal reinjection is not implemented, renewability of geothermal water is judged in a similar way as to normal groundwater. The characteristics of groundwater age can reveal the groundwater circulation rate and renewability (Huang et al. 2017b). The age of GG in Tangshan is thousands of years, indicating very low circulation rate and rare renewability (Huang et al. 2017b). The GG in Tangshan was mainly recharged by local precipitation and the area of the recharge zone (Tangshan Mountain) is much limited (about 7 km2), rather than a large catchment basin, as in other cases. Due to these characteristics, overexploitation would likely lead to depletion of geothermal water. Actually, rapid decline of the water table in Tangshan is already occurring, where all hot springs have vanished from the surface and some geothermal wells are being depleted, resulting from apparent overexploitation of the geothermal water. Continuous decline of the water table may accelerate the thermal breakthrough (cold-water recharge to the geothermal reservoir) which is detrimental for maintaining the reservoir temperature as stable (Axelsson 2010; Kong et al. 2014). To prevent the water table from further declining and to ensure the sustainable use of geothermal resources in Tangshan, continuous monitoring of the water table and a rational plan of utilization should be implemented. Used geothermal-water treatment and reinjection (Duan et al. 2011; Liu and Wang 2006) should be considered if possible, to maintain the geothermal water yield and reservoir pressure. In addition, to prevent the geothermal water from being contaminated and to ensure good water quality, the recharge zone (Tangshan Mountain) should be protected from being polluted.
Conclusions
A multi-tracer approach involving chemicals and isotopes (δ2H, δ18O, δ34S, 87Sr/86Sr, δ13C, 14C, 3H) was conducted to provide insight into the recharge source and groundwater circulation in TGS. The application of chemical geothermometers, including cation ratios and Silica solubility, as well as thermodynamic modeling, revealed reservoir temperatures of 51 °C in the western side and 74–87 °C in the eastern side of Tangshan Mountain, respectively, which needs a groundwater circulation depth of about 2.5 km. The geothermal water in TGS was recharged by past (1,777–9,155 years) local precipitation with depleted δ2H and δ18O, through the Cambrian and Ordovician carbonate formations area exposed on the upper part of the mountain. The parent geothermal water was cooled due to mixing with shallow cold karstic groundwater during upwelling with a cold-water mixing fraction up to 63%. The corrected 14C age of geothermal water is on the millennial scale, indicating a low circulation rate and rare renewability. The recovery of the water table occasionally occurring in some production wells may be attributed to the effect of pressure migration but not the present-day rainfall recharge.
This study provided key information on the water origin of TGS and the results are instructive and significant with respect to the sustainable exploitation of geothermal resources in Tangshan. It is recommended that a monitoring network of wells be established that would include regular measurements of the groundwater level, down-hole temperature and chemistry. Prediction of future changes in the flow and geo-temperature field would become possible if integrated with numerical reservoir modeling. Reinjection of used geothermal water is another possibility to be considered that would help maintain the pressure of the system. The methodology tested here can also be applied to evaluate other geothermal systems.
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Acknowledgements
Thanks are due to Prof. Huang Jinsheng and Prof. Luo Zhujiang for their discussions during the project implementation. Appreciation goes to Prof. Jin Zhengang and Prof. Li Yiman, who helped with stable isotope and hydrochemical analyses, respectively. The authors are also grateful to the two anonymous reviewers and guest editor Prof. Dr. Wenke Wang whose insightful comments were very helpful in improving the quality of the manuscript.
Funding
The reported study is partly financially supported by the National Natural Science Foundation of China (NSFC Grant 41430319), the 1st Geological Brigade of Jiangsu Geology and Mineral Exploration Bureau and the UCAS (UCAS [2015]37) Joint PhD Training Program.
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Lu, L., Pang, Z., Kong, Y. et al. Geochemical and isotopic evidence on the recharge and circulation of geothermal water in the Tangshan Geothermal System near Nanjing, China: implications for sustainable development. Hydrogeol J 26, 1705–1719 (2018). https://doi.org/10.1007/s10040-018-1721-6
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DOI: https://doi.org/10.1007/s10040-018-1721-6