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Volume 5 Issue 4
Dec.  2017
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GAN Hao-nan, LIN Wen-jing, YUE Gao-fan, et al. 2017: Research on the fault controlling mechanism of geothermal water in Zhangzhou Basin. Journal of Groundwater Science and Engineering, 5(4): 326-335.
Citation: GAN Hao-nan, LIN Wen-jing, YUE Gao-fan, et al. 2017: Research on the fault controlling mechanism of geothermal water in Zhangzhou Basin. Journal of Groundwater Science and Engineering, 5(4): 326-335.

Research on the fault controlling mechanism of geothermal water in Zhangzhou Basin

  • Publish Date: 2017-12-28
  • Fault has an important influence on the storage and movement of geothermal water. The Zhangzhou Basin is wholly located in a granodiorite rock mass. Due to the low permeability of granodiorite, faulted structure has an evident control action on the hydrothermal activity of geothermal fields. Hot springs in Zhangzhou Basin crack along Pingtan-Dongshan Fault to the northeastern direction and emerge along Fu’an-Nanjing Fault. Through measurement of the temperature of several hot springs in the Basin, we found the temperature along the northwestern direction of Zhangzhou-Tianbao Fault is high and the temperature gap between the two sides of Yangxi-Yuanshan Fault is huge; the estimation of geothermal reservoir temperature of geothermal water through quartz geothermometer indicates that the geothermal reservoir temperature of the northern area of Nanjing-Xiamen Fault is obviously higher than that of southern area. Such result indicates that Fault obviously obstructs underground heat source. Under the condition that the average geothermal gradient of the Zhangzhou Basin is set, the circulation depth of the geothermal water of the Zhangzhou Basin measured by geothermal reservoir temperature is 3 550-5 200 m and the circulation depth of the geothermal water of the north of Nanjing-Xiamen Fault is deeper than that of the South.
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  • WANG Jun, ZHOU Jia-ping. 1992. Medium and low temperature of geothermal resources in Huabei Plain and the effect of its application to environment (interchannel area is an example). Beijing: Seismological Press.
    LIU Tang-wei, SUN Zhan-xue, et al. 2016. Comparison of different numerical simulation results of Zhangzhou basin deep rock stratum temperature. Journal of East China University of Technology (Natural Science), 39(4):310- 318.
    Fournier R O. 1977. Chemical?geothermometers?and?mixing?models?for?geothermal?systems. Geothermics, 5(1-4):41-50.
    LIN Wen-jing, WANG Feng-yuan, et al. 2015. Site selection and development prospect of a hot dry rock resource project in Zhangzhou geothermal field, Fujian Province. Science and Technology Review, 33(19):28-34.
    ZHU Wen-xiao, TU Wan-sheng. 1988. Curie isodepth surface of the Zhangzhou area, south Fujian. Earth Science, 13(3):241-246.
    GAN Hao-nan, WANG Gui-ling, et al. 2015. Research on the occurrence types and genetic models of hot dry rock resources in China. Science & Technology Review, 33(19):22-27.
    F Horváth, B Musitz, et al. 2015. Evolution of the Pannonian basin and its geothermal resources. Geothermics, 53:328-352.
    HU Sheng-biao, XIONG Liang-ping. 1990. Reservoir modelling of Zhangzhou low temperature fracture zone system, Fujian, China. Geological Science and Technology Information, 9(4):65-71.
    YANG Li-zhong, LIU Jin-hui, et al. 2016. Study of the characteristics of radioactive heat production rate and hot dry rock resources potential in Zhangzhou city. Modern Mining, 563(3):123-127.
    ZHUANG Qing-xiang. 1988. Study on the formation model of geothermal fields in Zhangzhou. Earch Science-Journal of China University of Geosciences, 13(3):335-339.
    XIONG Shao-bai, JIN Dong-min, et al. 1991. Some characteristics of deep structure of the Zhangzhou geothermal field and it’s neighborhood in the Fujian Province. Acta Geophysica Sinica, 1:55-63.
    PANG Zhong-he. 1987. Geothermal system of Zhangzhou bain-research on formation model, thermal potential and distribution law of hot water. Beijing: Institute of Geology and Geophysics, CAS.
    XIONG Liang-ping, WANG Ji-yang, PANG Zhong-he. 1990b. Circulation depth of the thermal water in Zhangzhou geothermal field. Scientia Geologica Sinica, 4: 377-384.
    Minnan Geological Team in Fujian Province. 2007. Survey report of geothermal resources in Zhangzhou. Fujian Province: Minnan Geological Team.
    WANG An-dong, SUN Zhan-xue, et al. 2015. Radiogenic heat production of rocks from Zhangzhou, Southeast China and its implications for thermal regime of lithosphere. Science & Technology Review, 33(24):41-45.
    KE Long-sheng. 1997. Hydrothermal activity in Zhangzhou geothermal field and its formation mechanism. Journal of Oceanography in Taiwan Strait, 16(1):21-27.
    LI Da-xin, ZENG Lu-hai. 1988. The study of geothermal distribution in Zhangzhou geothermal area and a preliminary model of its geothermal formation. Earth Science- Journal of China University of Geosciences, 13(3):229-230.
    XIONG Liang-ping, WANG Ji-yang, PANG Zhong-he. 1990a. Convective and conductive heat flows in Zhangzhou geothermal field, Fujian Province, China. Acta Geophysica Sinica, 33(6):702-711.
    BAI Deng-hai, LIAO Zhi-jie, et al. 1994. A deduction of magma heat source of hot fields in the Tengchong through MT results. Chinese Science Bulletin, 39(4):344-347.
    HAN Qing-zhi, ZHANG Qing-xiang. 1988. On the source and pathway of hot water in Zhangzhou Basin, Fujian. Earth Science- Journal of China University of Geosciences, 13(3):271-277.
    PANG Zhong-he, WANG Ji-yang, FAN Zhi-cheng. 1990b. The study on stable oxygen and hydro?gen isotopes in the Zhangzhou Basin hydrothermal system. Acta Petrologica Sinica, 11(4):75-84.
    ZHAN Wei-zhen. 2008. Formation model of geothermal field and its relation with control structure in Zhangzhou. Safety and Envi-ronmental Engineering, 15(4):30-33.
    WANG Ji-yang. 1996. Medium and low tem-perature convective type geothermal system. Earth Science Frontiers, (3): 96-100.
    ZENG Yu-chao, SU Zheng, et al. 2012. Temperature distribution characteristics of bedrock fracture groundwater system at Zhangzhou geothermal field. Journal of Jilin University (Earth Science Edition), 42(3): 814-831.
    PANG Zhong-he, WANG Ji-yang, FAN Zhi-cheng. 1990a. Reservoir temperature of geothermal fields in Zhangzhou calculated through SiO2 hybrid model. Chinese Science Bulletin, 1:57-59.
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