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地下水流系统研究中的方法论探讨: 以CUG-武汉地下水流系统研究为例

梁杏 张人权 罗明明 孙蓉琳 靳孟贵 周宏 蒋立群

梁杏, 张人权, 罗明明, 孙蓉琳, 靳孟贵, 周宏, 蒋立群. 地下水流系统研究中的方法论探讨: 以CUG-武汉地下水流系统研究为例[J]. 地质科技通报, 2022, 41(1): 30-42. doi: 10.19509/j.cnki.dzkq.2022.0005
引用本文: 梁杏, 张人权, 罗明明, 孙蓉琳, 靳孟贵, 周宏, 蒋立群. 地下水流系统研究中的方法论探讨: 以CUG-武汉地下水流系统研究为例[J]. 地质科技通报, 2022, 41(1): 30-42. doi: 10.19509/j.cnki.dzkq.2022.0005
Liang Xing, Zhang Renquan, Luo Mingming, Sun Ronglin, Jin Menggui, Zhou Hong, Jiang Liqun. Discussion on methodology in research of groundwater flow system: A review of research on groundwater flow systems at CUG-Wuhan[J]. Bulletin of Geological Science and Technology, 2022, 41(1): 30-42. doi: 10.19509/j.cnki.dzkq.2022.0005
Citation: Liang Xing, Zhang Renquan, Luo Mingming, Sun Ronglin, Jin Menggui, Zhou Hong, Jiang Liqun. Discussion on methodology in research of groundwater flow system: A review of research on groundwater flow systems at CUG-Wuhan[J]. Bulletin of Geological Science and Technology, 2022, 41(1): 30-42. doi: 10.19509/j.cnki.dzkq.2022.0005

地下水流系统研究中的方法论探讨: 以CUG-武汉地下水流系统研究为例

doi: 10.19509/j.cnki.dzkq.2022.0005
基金项目: 

国家自然科学基金项目 41772268

国家自然科学基金项目 42172276

国家自然科学基金项目 42172286

国家自然科学基金项目 41807199

详细信息
    作者简介:

    梁杏(1958-), 女, 教授, 博士生导师, 主要从事水文地质学教学、基础理论与工程应用研究工作。E-mail: xliang@cug.edu.cn

  • 中图分类号: P641

Discussion on methodology in research of groundwater flow system: A review of research on groundwater flow systems at CUG-Wuhan

  • 摘要: 地球系统科学和地下水流系统理论的出现,标志着水文地质学进入新的发展时期。地下水流系统理论已成为水文地质学的新范式,其产生和发展,从方法论上为地下水问题的研究提供了新的启示。自20世纪80年代初以来,中国地质大学(武汉)地下水流系统组持续开展了地下水流系统理论与应用研究。试图从方法论的角度回顾与总结这些研究成果。地下水问题受多因素影响,研究应以"目标与问题导向相结合",靶向准确,才能在信息浩渺中不失方向,向着目标前行;研究时应采用"假设演绎法",先依据已有认识和资料演绎出应有的现象,再有目的地观察和寻求证据,或修改假设继续求证,直到假设被证实或证伪;演绎寻证过程,可以采用"控制性实验""信息提取与组织""多学科方法与手段融合"等技术方法。实例分析证实,控制性模拟实验使我们得出了地下水流模式的新认识;采用多通道的信息提取、加工和组织,构建地下水流系统模式,能够有效解决各类工程中的应用问题;多学科与手段融合、各种信息相互验证,提高了结果的可信度。以实例研究为基础,从研究方法上的总结能为正确认识和理解地下水流系统理论、推进新理论和新思路在水文地质研究中的应用提供参考。

     

  • 图 1  地下水流系统在Web of Science核心合集数据库文献数的年度变化趋势(1982-2021年)

    注:Web of Science核心合集数据库始建于1982年,1982年以前的文献未查询

    Figure 1.  Annual change trend of the number of papers about the groundwater flow system in the core collection database of Web of Science since 1982

    图 2  地下水流系统CNKI(中国知网)文献数的年度变化趋势(1982-2021年)

    Figure 2.  Annual change trend of the number of documents about the groundwater flow system according to CNKI(China Knowledge Network)(1982-2021)

    图 3  地下水流系统在CNKI的中国发文机构分布(1982-2021年)

    Figure 3.  Distribution of China organizations publishing papers on groundwater flow systems according to CNKI(China Knowledge Network)(1982-2021)

    图 4  地下水流系统物理模拟结果(引自文献[16])

    Figure 4.  Physical simulation results of groundwater flow systems in sand box

    图 5  针对“库区岩溶渗漏”问题的假设演绎与信息提取的研究思路框架

    Figure 5.  Framework of research ideas for hypothetical deduction and information extraction for the karst leakage problem in a reservoir area

    图 6  多级次水流系统模式的模拟实验研究设计

    Figure 6.  Simulation experiment research design of multi-hierarchical flow system

    图 7  砂箱实验得出不同入渗强度的地下水流系统(引自文献[16])

    a.河谷S1、S2、S3均为实际势汇; b.河谷S2、S3为潜在势汇

    Figure 7.  Groundwater flow patterns under different infiltration intensities resulted from sandbox experiments

    图 8  山西郭庄泉及龙子祠泉岩溶水系统特征的圈划(引自文献[34-35])

    Figure 8.  Devision of Guozhuang spring and Longzici spring karst water systems, Shanxi

    图 9  高岚河流域岩溶水系统划分(引自文献[41])

    Figure 9.  Division of karst water system in Gaolan River Basin

    图 10  香溪河流域古夫宽缓向斜区多级岩溶水流系统概念模型图(引自文献[41])

    Figure 10.  Schematic conceptual model of hierarchical karst water flow system in the wide syncline area of Gufu, Xiangxi River Basin

    图 11  末次盛冰期以来河北平原地下水流系统演变示意剖图(引自文献[48])

    a.18~15 ka(阶段Ⅰ);b.15~12 ka(阶段Ⅱ);c.距今2.5 ka~现今(阶段Ⅲ);实线表示活动的水流系统,虚线表示衰亡的水流系统;中部平原局部水流系统及滨海平原水流系统,资料不足,未予表示。1.基岩;2.第四系;3.盆地底界;4.咸水(ρ(TDS)>2 g/L);5.山前平原局部水流系统流线;6.区域水流系统流线;7.中部平原早期中间水流系统流线;8.中部平原晚期中间水流系统流线;9.地下水流域分界线;10.山前平原局部水流系统流域;11.区域水流系统流域;12.中部平原早期中间水流系统流域;13.中部平原晚期中间水流系统流域

    Figure 11.  Schematic representation of evolution of ground-water flow systems in Hebei Plain since the Last Glacial Maximum

    图 12  不同新构造运动条件下河间地块岩溶发育模式(引自文献[54])

    Figure 12.  Development patterns of karst under different neotectonic movement

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  • 收稿日期:  2021-12-27
  • 网络出版日期:  2022-03-02

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