Stable isotopes and hydrogeochemical evolutions of groundwater from a typical seismic fault zone in the Mt. Lushan region, Eastern China

Bao, Zhicheng; Hu, Le; Xiao, Jian; Zha, Xiaohui; Lv, Jian; Zhao, Ying

doi:10.3389/feart.2023.1285136

ORIGINAL RESEARCH article

Front. Earth Sci., 28 December 2023

Sec. Solid Earth Geophysics

Volume 11 - 2023 | https://doi.org/10.3389/feart.2023.1285136

This article is part of the Research Topic From Preparation to Faulting: Multidisciplinary Investigations on Earthquake Processes - Volume II View all 15 articles

Stable isotopes and hydrogeochemical evolutions of groundwater from a typical seismic fault zone in the Mt. Lushan region, Eastern China

Zhicheng Bao¹

Le Hu²*

Jian Xiao¹

Xiaohui Zha¹

Jian Lv¹

Ying Zhao¹

¹Jiangxi Earthquake Angecy, Nanchang, China
²Institute of Earthquake Forecasting, China Earthquake Administration, Beijing, China

We analyzed the major chemical components, hydrogen (δD) and oxygen isotopes (δ¹⁸O), and tritium activity in groundwater from Jiujiang well number 2 (JJ2) as well as atmospheric precipitation and water from the Maweishui spring and Tianhuajing reservoir in the Mt. Lushan region, Eastern China. The results show that the water in JJ2 is of the HCO₃-Ca·Mg type, with ionic components mainly arising from calcite and dolomite mineral dissolution. According to the δD and δ¹⁸O data, the groundwater of JJ2 mainly comes from atmospheric precipitation, and the recharge elevation is 554 m. Results for tritium activity indicate that JJ2 is fed by both an ancient water supply and a new water supply within a period of 10 years. These results demonstrate that JJ2 has characteristics of both shallow and deep circulating water, which implies that aquifers involving two different recharge sources rise to the well surface via different circulation paths. That is exactly why JJ2 is tectonically sensitive and could display a remarkable gas radon anomaly before the Ruichang-Yangxin M_L 5.0 earthquake in 2011. Our results also indicate that ascertaining the hydrological characteristics and cycling process of groundwater are crucial for understanding the earthquake anomalies and judging whether a seismic groundwater monitoring well is reliable or not.

1 Introduction

Underground fluid is proved to be an important carrier for transmitting information of geological evolution within the Earth and thus its geochemical characteristics and genesis are widely studied (Zhang, 1992; Che et al., 1998; Du and Kang, 2000; Liu, 2006; Li et al., 2022; 2023). Detailed researches involving the relationship between groundwater and surface runoff (Grasby et al., 1999; Su et al., 2009; Gu et al., 2017), the circulation process and water-rock interactions (He and Singh, 2019; Hosono and Masaki, 2020; Hosono et al., 2019; Nakagawa et al., 2020; Shi et al., 2020; Barberio et al., 2017; Skelton et al., 2014; Barberioet al., 2017; Zhou et al., 2020; Chen et al., 2015; Li et al., 2021; Martinelli and Dadomo, 2017; Skelton et al., 2019; Li et al., 2017; Bao et al., 2019; Du and Liu, 2003; Sun et al., 2016; Zhou et al., 2022; Tian et al., 2021; Song et al., 2006), the changes of chemical compositions before and after earthquakes (Tsunogai and Wakita, 1995; Claesson et al., 2004; Reddy and Nagabhushanam, 2011; Reddy et al., 2011; He and Singh, 2019; Hosono and Masaki, 2020; Hosono et al., 2019; Nakagawa et al., 2020; Shi et al., 2020; Barberio et al., 2017; Skelton et al., 2014; Barberioet al., 2017; Zhou et al., 2020; Chen et al., 2015; Zhao et al., 2023), and the earthquake anomaly verification (Liu and Ren, 2009; Zhang et al., 2014; Zhang et al., 2016; Zhou et al., 2021). All these studies demonstrated that making clear the origin and forming process of underground fluid is the prerequisite for identifying earthquake precursors (Li et al., 2022; 2023).

Ruichang-Yangxin M_L 5.0 earthquake, occurred on 10 September 2011, is one of the large earthquakes occurred in the central and eastern regions of China in recent years. About 1 month before the earthquake, radon in groundwater from Jiujiang well number 2 (herein after JJ2) increased rapidly, showing a remarkably high value anomaly. The reason that JJ2 can exhibit such anomaly could be the fact that JJ2 is a cold spring located on the fault zone with a moderate groundwater age as there is a hypothesis that neither young and old groundwater can reflect the change of the geochemical environment in the crust effectively while groundwater with moderate age is more able to show relatively complete abnormal forms before earthquakes (Pan and Gao, 2001). But to better understand the cause of this radon anomaly, more detailed works need to be done on the groundwater characteristics in the JJ2. Therefore, this paper attempts to give a reasonable explanation to the seismic hydrogeochemical characteristics of the well and the causes of the pre-earthquake anomaly of gas radon through the analysis results of hydrochemical composition, hydrogen and oxygen isotopes and well water dating. This would provide a scientific basis for further understanding the recharge cycle and anomaly formation in shallow wells on the fault zone and exploring the formation mechanism of gas radon anomaly in areas with few earthquakes and weak earthquakes and its response relationship with regional tectonic activities.

2 Geological setting

The JJ2 is a typical well at the Jiujiang Seismic Monitoring Centre station (JJS) (29.65°N, 115.33°E, 110 m) which is located in the northwestern side of Lushan Mount (Mt Lushan) in the north of Jiangxi province and tectonically belongs to the junction zone of Yangtze block (Jiangnan ancient land) and Dabie Mountain block (Lv et al., 2008). The climate here is subtropical monsoon, with annual average temperature of 16.7°C and average annual precipitation of 1,300 mm. Active faults are well developed in the area including the NE-trending Tanlu Fault, the NW-trending Xiangfan-Guangji Fault, and the NEE trending Xiajia-Weijialing Fault (Figure 1). The Xiajia-Weijialing fault near the JJ2 is a left strike-slip fault on the edge of the northwestern margin of Lushan Mountain. The fault extends for about 8 km wide and about 11.5 km long, with a general tendency 320°–330° and an inclination of 60∼70°. The study area is seismically active, within which three earthquakes with magnitude above 3.0 have occurred since 2005, including the Jiujiang-Ruichang M_L 5.7 earthquake in 2005, the Ruichang-Yangxin M_L 5.0 earthquake in 2011, and the Jiujiang M_L 3.7 earthquake in 2015 (Figure 2).

FIGURE 1

FIGURE 1. (A) Structural geological map of the study area. (B) Schematic diagram of well structure and aquifers of JJ2. (C) Location of the study area.

FIGURE 2

FIGURE 2. Time-series map of earthquakes above M_L 2.0 within 150 km of the Jiujiang seismic station.

JJ2 is a structurally confined artesian well started running since 2008. The well has the depth of 71 m and the casing of 11.9 m. From the surface to 6.2 m, it is composed of loam and gravel of Lianwei Formation of Quaternary; 6.2–11.9 m is composed of strongly weathered carbonaceous limestone of Piyuancun Formation of Sinian; and 11.9–71 m is composed of Lower Proterozoic carbonaceous limestone (Figure 1). The well has two aquifers at 17–22.5 m and 55–63.5 m respectively, and the current daily discharge is approximately 300 tons. There is a reservoir about 1 km away and a river about 50 m away which comes from the Maweishui (MWS) spring in the Mt Lushan.

3 Sampling and analyzing methods

Atmospheric precipitations from the courtyard of JSS (JIJ), Guomiansichang (GMS), Xingang (XG), and Lushan Meteorological Bureau (LMB) were collected for δD and δ¹⁸O analysis. Water samples from the JJ2, MWS spring, and Tianhuajing reservoir (THJ) were collected for δD, δ¹⁸O and chemical analysis. The sampling bottle was high density polyethylene (HDPE) screw cap bottle with a thin neck. In order to avoid contamination of samples, sampling bottle was cleaned with deionized water before collecting samples, and then with the collected water sample for three times. By overflow method, the bottle was capped immediately after filling, and the mouth wrapped with parafilm. Two samples were collected at each sampling point. A total of 239 effective water samples were obtained, of which 198 were obtained from atmospheric precipitation, and 41 from JJ2, THJ reservoir and MWS spring water. The collection method was to connect a sampling bottle under the rain gauge. In order to prevent sundries from entering the sampling bottle, a ping-pong ball was placed in the rain gauge. Effective precipitation with long rainfall duration was used for test and analysis. Water samples from JJ2, which was used for hydrogen and oxygen isotope testing, were collected once every 2 weeks, and water samples from four different seasons were selected for hydrochemical composition analysis. The water from THJ reservoir and MWS spring were collected once for hydrogen and oxygen isotope and water chemical composition analysis. All samples were filtered through a 0.22 μm membrane before measurement.

Water temperature, pH value, and total dissolved solids (TDS) were recorded in the sampling point, and each parameter was measured thrice continuously and averaged. The hydrochemical components and hydrogen and oxygen isotope analysis of the samples were completed in the Key Laboratory of Crustal Dynamics (Underground Fluid Dynamics Laboratory Unit) of China Earthquake Administration, where major element analysis equipment used was ICS-2100 ion chromatograph (flow accuracy <0.1%). Oxygen isotope analysis equipment used was Picarro liquid water isotope analyzer (L2130-i type, United States of America), and the results of stable isotopes of hydrogen and oxygen were expressed in thousandths difference relative to Vienna standard mean marine water (VSMOW):

δ = (R_{s a m p l e} - R_{s \tan d a r d}) / R_{s \tan d a r d} \times 1000 (1)

Here, R_sample represents the ratio of ¹⁸O/¹⁶O (D/H) in the samples; R_standard represents the ratio of ¹⁸O/¹⁶O (D/H) in VSMOW. The accuracy of the tests conducted was determined to be δ¹⁸O < 0.05‰ and δD < 0.5‰. The tritium isotope radioactivity of the samples was tested at the Institute of Hydrogeology and Environmental Geology, Chinese Academy of Geological Sciences, using a Quantulus-1220 ultra-low background liquid scintillation spectrometer. Liquid scintillation counting was employed as the analytical method.

SD-3A Intelligent Digital Radon Meter operates based on the flashing light method. When radon gas enters the scintillation chamber, the α particles emitted from the decay of radon and its progeny cause the “fluorescent body” on the wall of the sampler in the scintillation chamber, which is made of ZnS (Ag), to emit weak flashes of light. The photomultiplier inside the instrument then detects and converts these flashes of light into electrical impulses. These electrical impulses are further amplified by the electronic circuits, and finally, the processor records the corresponding electrical impulse signals. Subsequently, the processor calculates the radon content (concentration) in the measured gas (or soil) using the principle of pulse count rate, which is determined by the number of electric pulses recorded per unit time.

4 Results

4.1 Hydrochemical characteristics

The main analytical phases of hydrochemistry in the study area (pH, TDS, Ca²⁺, Mg²⁺, Na⁺, K⁺, F⁻, Cl⁻, SO₄²⁻, and HCO₃⁻) are shown in Table 1. Generally, the pH values of groundwater and surface water were weakly alkaline, while that of MWS Spring was acidic. The TDS of JJ2 water, THJ water, and MWS water were 247.07∼258.15 mg/L, 46.80 mg/L, and 42.90 mg/L respectively. The TDS of groundwater was higher than that of surface water. As can be seen in Piper’s three-line diagram, the main positive ions include Ca²⁺, Mg²⁺, and Na⁺, and the main negative ions are HCO₃⁻ and Cl⁻. In the piper chart, the water samples are mainly distributed in three zones (Figure 3). Among them, the water samples on the first zone (JJ2 and THJ) belongs to the HCO₃−Ca·Mg type. Atmospheric precipitations (JIJ and GMS) in the second zone belongs to the Cl−Na type. Other water samples are located in the third zone of the piper diamond graph that belong to the HCO₃−Na type.

TABLE 1

TABLE 1. Summary of stable isotopes and chemical compositions of different water bodies in the Lushan regions [“-” represents no text data, “*” represents data from Bao et al. (2022)].

FIGURE 3

FIGURE 3. Piper diagram of chemical macronutrients.

4.2 Characteristics of hydrogen and oxygen isotope composition

The measured values of hydrogen isotope (δD) and oxygen isotope isotopic composition (δ¹⁸O) in JJ2 was −43.87‰∼-39.69‰ and −7.42‰∼-6.09‰, respectively. The mean values of δ¹⁸O and δD for the JJ2 are −6.99‰ and −42.55‰ respectively. The measured value of δD and δ¹⁸O in atmospheric precipitation was −126.77‰∼22.11‰ and-15.97‰∼0.48‰, respectively. The mean values of δ¹⁸O and δD for the atmospheric precipitation are −7.67‰ and −48.68‰ respectively. According to the measured values of hydrogen and oxygen isotopes of atmospheric precipitation, the local atmospheric precipitation line was: δD=8.6 δ¹⁸O+18.8 (r=0.97, n= 198), and the slope and intercept were roughly the same as those in Nanjing (Wang et al., 2013; Liu et al., 2014). According to the δD and δ¹⁸O of groundwater in JJ2, the evaporation line of groundwater at JJS was fitted as: δD= 3.0 δ¹⁸O-21.9 (r=0.86, n=34). Moreover, it could be observed that δD and δ¹⁸O of the JJ2 water are mainly distributed near the meteoric water line (Figure 4). Compared with the local precipitation line and the global atmospheric precipitation line, the slope and intercept of the fitted evaporation line were obviously smaller, which indicates that the whole water belongs to the atmospheric genetic type and experienced certain evaporation before the atmospheric precipitation is replenished (Craig, 1961; Giggenbach, 1992).

FIGURE 4

FIGURE 4. Distribution chart of δD and δ¹⁸O in the water sample.

4.3 Gas radon concentrations

The intelligent digital radon-detectors (SD-3A) samples once every hour. This paper provides the observed gas radon data time series from January to December 2011 (Figure 9C). It can be seen that the normal background values are varying in range of 0.3 Bq/L to 2.0 Bq/L. However, the value began to rise rapidly since 12th of August 2011 and reach a maximum value of 28.5Bq/L on 30th of August. After that, the value began to decline. During the process, the Ruichang-Yangxin M_L5.0 earthquake occurred on 11 September, which is about 27 km away from the JJ2.

5 Discussion

5.1 Groundwater circulation depth

Groundwater geochemical evolution is mainly controlled by various chemical reactions between water and rock, and identifying these reactions is the basis of groundwater geochemical evolution research (Giggenbach, 1988). In this paper, Na-K-Mg triangle graphic method is utilized to analyze the chemical equilibrium reaction characteristics and cycle depth of groundwater components. The Na–K–Mg triangular plot (Figure 5) shows the sample of JJ2 and THJ are in immature water zone, indicating that they are not fully equilibrated with the reservoir rocks. The sample of MWS plot in the partial equilibrated water zone, which show that part of water-rock interaction had reached equilibrium, the circulating depth of underground water was deep.

FIGURE 5

FIGURE 5. Na-K-Mg diagram and partial enlargement of water sample.

Cation geothermometers can be used to estimate approximate reservoir temperatures. In this study, the Na-K-Mg triangulation based on Na-K and K-Mg geothermometers were used to assess the thermal storage temperature of underground water samples. According to the temperature marking in Figure 5, the reservoir temperatures of groundwater in JJ2 was about 60∼80 °C, and the MWS sample was about 160°C.

According to the reservoir temperature, the circulated depth calculation formula shown as follows is adopted

Z = Z_{0} + (T - T_{0}) / T_{g r a d} (2)

Here, Z represents the circulation depth (km); Z₀ represents the depth of the constant temperature zone (km); T represents the reservoir temperature (°C); T₀ represents the temperature of the constant temperature zone (°C), namely, the local average temperature; Tgrad represents the geothermal gradient (°C/km) reflecting the geothermal change per kilometer of the place below the constant temperature zone (Xiong et al., 1990). Based on the previous studies on groundwater in the study area, we selected the geothermal gradient Tgrad of 21.3°C/km (Wang et al., 2023a), the annual mean temperature T₀ in the Jiujiang is 17.5°C, and the Z₀ is 20 m. The circulation depth of the JJ2 and MWS are about 2015∼2,954 m and 6710 m respectively, which implies that the circulating path of groundwater in MWS spring was different from that in JJ2. The circulation depth and the reservoir temperature of the JJ2 and MWS are positive-related. Cool waters are likely involved during the long circulation pathways between the reservoir and the spring vent.

5.2 Recharge elevation

The linear regression between different elevations and their hydrogen and oxygen isotope ratios could fit the elevation gradient of oxygen isotopes in the study area. When studying the groundwater recharge elevation, “isotope elevation gradient” can be used in a local area. According to previous research results (Ou et al., 2011), the elevation gradient of δ¹⁸O and δD in Lushan area is 0.188‰/100 m and 0.0138‰/100 m respectively. The recharge elevation of groundwater in the study area can be estimated by using the elevation gradient value, and its calculation formula is as follows:

H = \frac{(δ G - δ P)}{K} + h (3)

Here, H represents the recharge elevation (m), h represents the sampling point elevation (m); δ_G represents the isotopic composition of underground water (‰), δ_P represents the atmospheric precipitation near the sampling point (‰); K represents the isotopic altitude gradient (‰/100 m). Considering the probably oxygen drift caused by water-carbonate rock interaction (Pang et al., 2017), K_δD = 0.0138‰/100 m was used in this study. So, the calculated recharge elevation calculated is 554 m.

5.3 Groundwater age

Tritium is a radioactive isotope of hydrogen, with a half-life of 12.43 a (Lucas and Unterweger, 2000), which can be subdivided into natural tritium and artificial tritium according to its origin. Natural tritium mainly comes from cosmic rays, and artificial tritium mainly comes from human activities such as nuclear experiments. Tritium is released during the month of precipitation, surface water, and groundwater, and is not easy to react with environmental media along with hydrogeological and other processes for life, but only follows the radioactive law, with the change being quite independent (Wang, 1991). Based on the inherent characteristics of tritium, it tends to estimate the age of groundwater and discriminate the source of recharge. The tritium content in the natural state is very low (<0.5). According to previous studies (Gu, 2011), when the activity is less than 1.0 Tritium Unit (TU), the old water was replenished before 1953, 1∼3 TU, old water mixed with new water for nearly 10 years. According to recent study, the tritium activity of JJ2 is 1.6 ± 0.6TU (Bao et al., 2022), which indicated that the JJ2 has both old water supply and nearly 10 years new water supply, the groundwater was of moderate age and had the conditions to reflect the dynamic changes of medium and environment in the fault zone (Zhang et al., 2019). It also implied that the two aquifers in JJ2 have different circulation paths and recharge sources.

5.4 Petrographic compositions involved in dissolution and hydraulic relationship

The ratio of ion molar concentrations in groundwater is often used to discriminate the source of dissolved ionic minerals in the water samples (Su et al., 2022). γCl/γNa+K ratios of most waters fall below 1:1 ratio line (Figure 6A), implying that cation exchange and weathering of silicates (NaAlSi₃O₈+8H₂O→Na⁺+Al(OH)₄ +3H₄SiO₄) may be significant processes along the JJ2 (Xiao et al., 2022; Wang et al., 2023b). As shown in Figures 6B, C, γHCO₃/γCa in the waters of JJ2 fall in the zone between lines 1:1 and 1:2, and the ratio of γHCO₃/γMg+Ca in all waters of JJ2 mostly fall along the line 1:1, combined with the chemical types of HCO₃-Ca·Mg in JJ2, suggesting that the dissolution of calcite and dolomite are relevant to the lixiviation of carbonate. This phenomenon is also consistent with the lithological characteristics of the strata around JJ2. As shown in Figure 1, the stratigraphic lithology around the aquifer of JJ2 consists of carbonaceous greywacke, siliceous greywacke and sandstone, constituted mainly by calcites, dolomites, quartz, feldspars and clay minerals. So, Ca²⁺ and Mg²⁺ mainly originate from the dissolution of carbonates (calcites and dolomites), as well as some silicate minerals such as feldspars, which is further evidenced by the results in Figure 6D where the JJ2 samples fall mainly in the calcite dissolution zone, and occasionally in the dolomite dissolution zone.

FIGURE 6

FIGURE 6. (A) Relationships between Na⁺ +K⁺ and Cl⁻ of JJ2. (B) Relationships between Ca²⁺ and HCO₃⁻ of JJ2. (C) Relationships between Mg²⁺ +Ca²⁺ and HCO₃⁻ of JJ2. (D) Relationships between Ca²⁺ and Mg²⁺of JJ2. (E) Relationships between Ca²⁺ and SO₄²⁻of JJ2.

Scherer diagram can intuitively reflect the chemical characteristics of different water bodies. It is generally believed that waters with strong morphological consistency may have similar sources and circulation processes. Therefore, Scherer diagrams are often used to distinguish the hydraulic relationships of different water bodies. (Craig, 1961; Zhang et al., 2019). As shown in Figure 7, it can be found that the ion sources of MWS and THJ are more complex compared to JJ2, in which MWS mainly includes calcite, dolomite, silicate and gypsum, while THJ mainly include calcite, dolomite, silicate, gypsum and Halite. The ion content curves of MWS and JJ2 are significantly different from each other, suggesting that they are not hydraulically connected. In the piper diagrams (Figure 3), the water of JJ2 and MWS belong to different water chemistry types, which further implies that they have different origins. Although the hydrochemistry types of JJ2 and THJ are the same, the morphology of their ion content curves are still very different, so it is discriminate that they are weakly hydraulically connected to each other. This is similar to the results reflected in Figure 6.

FIGURE 7

FIGURE 7. Scherer diagrams shows the characteristics of constant components.

5.5 Response of observation well to seismic activity

The evolution of d excess of groundwater is mainly controlled by surrounding rocks, oxygen-bearing components, lithology and aquifer sealing conditions, water retention time, and physical and chemical properties of water. The d value of JJ2 was 9.03∼15.93, with the mean value of 13.40, which belongs to modern circulating leaching water (Bao et al., 2021). This is consistent with the fact that JJ2 samples are located in the immature area of the Na-K-Mg block, and have a shallow recharging elevation. That is to say, JJ2’s aquifer cycle recharge faster and do not react adequately with the surrounding rocks. The δD and δ¹⁸O compositions indicates that the source of water in JJ2 is of the atmospheric precipitation genesis type, so the main recharge source of water in the aquifer in JJ2 is the atmospheric precipitation via infiltration through the rock fissures (Figure 8C). However, some deep-derived fluids may also get involved as evidenced by the results of the tritium activity analysis.

FIGURE 8

FIGURE 8. (A) Schematic diagram of the observation well. (B) The source of escaping gas radon.

Radon, as an earthquake-sensitive component of subsurface fluids, is one of the longest observed and most widely used monitoring items in the field of earthquake forecasting. Abundant studies have proved that there are significant Rn anomalies before the occurrence of earthquakes (Igarashi et al., 1995; Sugisaki et al., 1996; Liu and Ren, 2009; Muto et al., 2021). One month before the Ruichang-Yangxin M_L 5.0 earthquake (<50 km), escaping radon in JJ2 showed significant high value anomalies (Figure 9C). Based on the results above, we think that there are two reasons resulting such sensitive response. Firstly, the JJ2 is located right on the fault, so its aquifer is connected well to the fault fracture zone which provides abundant pathways for circulation of substances in the underground fluid in the preparation process of earthquakes (Figure 8A); Secondly, the JJ2 is fed by moderate aged water, which can promptly reflect the changes in the geochemical environment within the earth’s crust and show a more complete pattern of anomaly before the earthquake. In addition, the water level and water temperature measurements in the observation wells did not observe obvious precursor anomalies before the earthquakes (Figures 9A, B), indicating that the hydrophysical observations were not sensitive or the sensitivity of the instruments was not enough to capture the significant anomalies.

FIGURE 9

FIGURE 9. (A) Time series diagram of water temperature from JJ2. (B) Time series diagram of water level from JJ2. (C) Time series diagram of gas radon concentration from JJ2.

6 Conclusion

In this study, the water samples from the JJ2 well, THJ reservoir, MWS spring, and local atmospheric precipitations were collected and analyzed, based on which responding mechanism of water in JJ2 to tectonic activities were discussed. Main conclusions were obtained as follows:

(1) The water type of the JJ2 and THJ is HCO₃-Ca-Mg type, and of MWS spring is HCO₃-Na type. The JJ2 water experienced weak water-rock interactions and belongs to the immature water, with the circulating depth of 2015∼2,954 m. MWS spring water experienced relative more intense water-rock interactions and is close to the partially equilibrated water, having the circulating depth about 6710 m. In addition, the waters from the JJ2, MWS spring, and THJ reservoir are not hydraulically connected.

(2) The JJ2 water is mainly a modern leaching water of atmospheric origin, with recharge elevation of about 554 m, and partially exchanged with fluids from deep parts of the fault.

(3) Due to the JJ2 is located right on the fault and has characteristics of both shallow and deep circulating water, JJ2 water can respond to regional tectonic activities sensitively as evidenced by the Radon anomaly before the Ruichang-Yangxin M_L 5.0 earthquake in 2011.

Data availability statement

The original contributions presented in the study are included in the article/supplementary material, further inquiries can be directed to the corresponding author.

Author contributions

ZB: Investigation, Methodology, Writing–original draft. LH: Conceptualization, Funding acquisition, Writing–review and editing. JX: Investigation, Writing–original draft. XZ: Investigation, Methodology, Writing–original draft. JL: Data curation, Investigation, Writing–original draft. YZ: Investigation, Writing–original draft.

Funding

The author(s) declare financial support was received for the research, authorship, and/or publication of this article. This study was funded by Open Fund from Engineering Research Center for Seismic Disaster Prevention and Engineering Geological Disaster Detection of Jiangxi Province (No. SDGD202215), the National Natural Science Foundation of China, China (No. 41861022), and the Spark Program of Earthquake Technology of CEA (No. XH18024Y). This study is a contribution of IGCP-724 project.

Acknowledgments

The authors are grateful to the Editor and reviewers for their constructive comments and suggestions. We thank Xiaobin Ou and Rengui Huang for handling earthquake data, and International Science Editing Company for polishing the language.

Conflict of interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

The reviewer XZ declared a shared affiliation with the author LH to the handling editor at time of review.

Publisher’s note

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References

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