苏北盆地典型地区中低温地热流体地球化学特征研究

doi:10.16108/j.issn1006-7493.2020099

高校地质学报 ›› 2022, Vol. 28 ›› Issue (2): 262-273.DOI: 10.16108/j.issn1006-7493.2020099

苏北盆地典型地区中低温地热流体地球化学特征研究

邹鹏飞^{1, 2}，邱杨³，范迪富¹

1. 江苏省地质调查研究院，南京 210018；
2. 南京大学地球科学与工程学院，南京 210023；
3. 江苏华东基础地质勘查有限公司，南京 210007

出版日期:2022-04-20 发布日期:2022-04-27

Study on Geochemical Characteristics of Mid-Low Temperature Geothermal Fluid in Representative Area of Subei Basin

ZOU Pengfei^1,2，QIU Yang³，FAN Difu¹

1. Geological Survey of Jiangsu Province, Nanjing 210018, China;
2. School of Earth Sciences and Engineering, Nanjing University, Nanjing 210023, China;
3. Jiangsu East China Basic Geological Exploration Co., Ltd, Nanjing 210007, China

Online:2022-04-20 Published:2022-04-27

摘要/Abstract

摘要： 苏北盆地作为江苏省地热地质条件最优的地区，发育丰富的中低温地热资源。文章选择存在已探明的中温地热井及干热岩验证孔所在的盆地区作为研究区，利用地热流体携带的地球化学信息，了解深部地热储层基本特征及不同深度地热资源的成生关系。结果表明：研究区地热流体中优势阳离子为Na+，阴离子呈复合离子型，以Cl-为主，Na+、TDS与Cl-均有着非常好的正相关性。经Na-K-Ca阳离子地热温标与SiO2地热温标法估算研究区地热流体热储温度介于73.8~145.1℃，推测黄荡地热田深部地热流体循环深度为2.1~2.8 km。通过定量计算，获得了地热流体补给高程范围为203.5~418.5 m。经过贝叶斯算法校正后的地热流体14C年龄自西向东呈增加趋势，与地热流体自西向东的径流方向有关，补给区可能位于研究区西南侧的沿盱眙老子山、明光、滁州分布的张八岭丘陵区。结合地热流体循环深度、循环周期（地热流体年龄）、氢氧同位素补给高程、热储温度及宝应1井测井成果，首次建立了宝应黄荡地热田的成矿模式。

关键词: 苏北盆地, 地热流体, 热储温度, 地球化学, 黄荡地热田

Abstract: The Subei Basin was enriched with medium-low temperature geothermal resources. This paper selected one representative area of the Subei Basin where one proven middle-temperature geothermal well and a hot-dry-rock verification hole were found as the study area. We employed the geochemical information carried by the geothermal fluid to have knowledge of the basic characteristics of deep geothermal reservoirs and the formation of geothermal resources at different depths. Results showed that the dominant cation in the geothermal fluid in the study area was Na+, however, the anion was of composite ion type, mainly Cl-. There was a good positive correlation beween Na+, TDS and Cl-. The calculation results of geothermal reservoir temperature were 73.8-145.1℃ estimated by the cations and silica geothermometer. In addition, the deep circulation depth of geothermal fluids in the Huangdang geothermal field was estimated to be 2.1 km. Through quantitative calculation, the elevation of recharge area for the geothermal fluids has been estimated from 203.5 m to 418.5 m. The 14C age of the geothermal fluid corrected by Bayesian algorithm showed an increasing trend from west to east, which was related to the direction of runoff of the geothermal fluid. The recharge area might be located in Zhangbaling Hilly area along the Xuyi Laozi Mountain, Mingguang city as well as Chuzhou city on the southwest side of the study area. The hydrogen and oxygen isotopic composition of the atmospheric precipitation in the recharge area was relatively consistent with that of the geothermal fluids, which further demonstrated the rationality of the inference of recharge elevation. According to the circulation depth of geothermal fluids, circulation period（or revised age of the Huangdang geothermal field）, recharge elevation, geothermal reservior temperature, and logging results, the mineralization model of the Huangdang geothermal field in Baoying county was established for the first time.

Key words: Subei Basin, geothermal fluid, geothermal reservoir temperature, geochemistry, Huangdang geothermal field

中图分类号:

P314

邹鹏飞, 邱杨, 范迪富. 苏北盆地典型地区中低温地热流体地球化学特征研究[J]. 高校地质学报, 2022, 28(2): 262-273.

ZOU Pengfei, QIU Yang, FAN Difu. Study on Geochemical Characteristics of Mid-Low Temperature Geothermal Fluid in Representative Area of Subei Basin[J]. Geological Journal of China Universities, 2022, 28(2): 262-273.

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苏北盆地典型地区中低温地热流体地球化学特征研究

Study on Geochemical Characteristics of Mid-Low Temperature Geothermal Fluid in Representative Area of Subei Basin

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