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    Volume 48 Issue 3
    Mar.  2023
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    Article Navigation >  Earth Science  > 2023  >  48(3): 958-972
    Jiang Ying, Li Jie, Xing Yifei, Liu Yulian, Wang Huiqun, Teng Yanguo, Wang Guiling, 2023. Evaluation of Geochemical Geothermometers with Borehole Geothermal Measurements: A Case Study of the Xiong'an New Area. Earth Science, 48(3): 958-972. doi: 10.3799/dqkx.2022.385
    Citation: Jiang Ying, Li Jie, Xing Yifei, Liu Yulian, Wang Huiqun, Teng Yanguo, Wang Guiling, 2023. Evaluation of Geochemical Geothermometers with Borehole Geothermal Measurements: A Case Study of the Xiong'an New Area. Earth Science, 48(3): 958-972. doi: 10.3799/dqkx.2022.385
    shu

    Evaluation of Geochemical Geothermometers with Borehole Geothermal Measurements: A Case Study of the Xiong'an New Area

    doi: 10.3799/dqkx.2022.385
    • 1.

      College of Water Sciences, Beijing Normal University, Beijing 100875, China

    • 2.

      Engineering Research Center of Groundwater Pollution Control and Remediation, Ministry of Education, Beijing 100875, China

    • 3.

      Chinese Academy of Geological Sciences, Beijing 100037, China

    • 4.

      Deep Earth Science and Exploration Technology Laboratory, Ministry of Natural Resources, Beijing 100037, China

    • 5.

      Geothermal and Hot Dry Rock Exploration and Development Technology Innovation Center, Ministry of Natural Resources, Beijing 100037, China

    • Received Date: 2022-09-14
      Available Online: 2023-03-27
    • Publish Date: 2023-03-25
      Abstract
    • The geochemical geothermometer is a common method for estimating the temperature of deep thermal reservoirs, which is widely used where no boreholes are drilled or the borehole depths do not reach the geothermal reservoir. However, the calculation results of the geochemical geothermometer were generally compared to the wellhead temperature in the previous studies. Comparison studies with the measured temperature of the borehole are few, which results in uncertainty of the geothermometers. In this study, 12 geothermal wells in the geothermal field with detailed research basis and abundant data in Xiong'an New Area, Jizhong depression, North China Plain, were selected to evaluate the reliability of the geothermometer in conjunction with water temperature measurement, borehole logging, and geothermal water collection and analysis. Nineteen geochemical geothermometers were used to estimate the thermal storage temperature of geothermal water after the evolution of water-rock interaction and multimineral thermodynamic equilibrium simulation. And then the results were compared with the measured borehole temperature and wellhead temperature. Results show that when the wellhead temperature in the study area is less than 70 ℃, the wellhead temperature falls within the range of the actual borehole temperature from the thermal reservoir roof to the floor. However, when the wellhead temperature exceeds 100 ℃, the wellhead temperature is lower than the thermal reservoir roof temperature and much lower to the bottom plate temperature. They are affected by several factors such as cooling, decompression, phase separation, CO2 degassing, and SiO2 precipitation during the transport process, which should be paid great attention in the future. Secondly, the geothermal water in Jixian karst-fissured reservoir belongs to immature water, and the cation geothermometer is not applicable, while the geothermal water in the porous Neogene sandstone reservoir is mainly located in a partial equilibrium area which implies the feasibility of both cation and SiO2 geothermometer. The borehole temperatures were used to verify the suitable geothermometers. It is found that the chalcedony solubility geothermometer is suitable for Jixian karst-fissured reservoir with a deviation of 6.2 ℃, while the Na-K geothermometer and chalcedony geothermometer are suitable for the porous Neogene sandstone reservoir with a deviation of 6.0 ℃ and 3.4 ℃, respectively. Finally, a variety of geothermometers are recommended to be selected with constraints of stratigraphic information, rock characteristics, wellhead temperature, and so on. And if the borehole logging is not available, underground temperature can be roughly understood with geochemical geothermometers at different sampling depths under the same geological structural unit. Our results have significant implications for the application of geochemical geothermometers and sustainable management of geothermal resources.

       

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