地下水与湖泊交互作用的研究趋势与前沿

杨泽森; 林晶晶; 常启昕; 周爱国; 黄小龙

doi:10.19509/j.cnki.dzkq.tb20240463

地下水与湖泊交互作用的研究趋势与前沿

doi: 10.19509/j.cnki.dzkq.tb20240463

杨泽森^{1, 2,},
林晶晶^2, ,,
常启昕³,
周爱国¹,
黄小龙²

1.
中国地质大学(武汉)环境学院, 武汉 430078
2.
生态环境部长江流域生态环境监督管理局生态环境监测与科学研究中心, 武汉 430010
3.
成都理工大学环境与土木工程学院, 成都 610059

基金项目:

国家自然科学基金长江水科学研究联合基金项目 U2240213

详细信息

作者简介:
杨泽森, E-mail: zesen_yang@foxmail.com

通讯作者:
林晶晶, E-mail: jjlin90@163.com

中图分类号: P641.2
计量
- 文章访问数: 86
- PDF下载量: 34
- 被引次数: 0
出版历程
- 收稿日期: 2024-08-18
- 录用日期: 2024-10-24
- 修回日期: 2024-10-24

Research trends and frontiers of groundwater-lake interaction

1.
School of Environmental Studies, China University of Geosciences(Wuhan), Wuhan 430078, China
2.
Changjiang Basin Ecology and Environment Monitoring and Scientific Research Center, Changjiang Basin Ecology and Environment Administration, Ministry of Ecology and Environment, Wuhan 430010, China
3.
College of Environment and Civil Engineering, Chengdu University of Technology, Chengdu 610059, China

More Information

Author Bio:
YANG Zesen, E-mail: zesen_yang@foxmail.com

Corresponding author: LIN Jingjing, E-mail: jjlin90@163.com

摘要

摘要:
为了解地下水与湖泊交互作用的研究趋势与前沿, 基于Web of Science数据库对相关文献进行了总结回顾, 依据VOSviewer辅助梳理了地下水与湖泊交互作用研究主题的发展历程, 结合CNKI数据库核心文献综合探讨了领域内的热点主题和难点问题, 总结了主要的热门研究手段, 并对该领域的未来发展趋势进行了预测和展望。分析发现, 地下水与湖泊交互作用研究依次经历了个体论、还原论、整体论3个发展阶段。当前的热点研究主题主要包括地下水与湖泊的水量交互、溶质传输以及生境互馈三大方面, 并将面临交互的时空异质性、交互界面的生物地球化学过程以及含水层对湖泊生态修复的时滞性等难点问题。稳定/放射性同位素、温度示踪、卫星遥感和数值模型是目前研究的热门手段, 且存在数据精度与覆盖范围相矛盾的共有应用缺陷。未来该领域的研究将迎来其发展的第Ⅳ阶段, 即大数据论。在这个阶段, 首先要依靠智慧数据进行精细监测, 提高地下水与湖泊交互动态变化过程的刻画精度; 其次应增效界面的数据挖掘, 准确量化地下水与湖泊交互界面的溶质传输通量; 然后还要建全数字生态文明, 全面赋能地下水与湖泊的生境互馈研究与生态环境保护, 促进该领域的综合发展。
- 地下水与湖泊交互 /
- 地下水与地表水交互 /
- 湖泊生态修复 /
- VOSviewer
Abstract: Significance
To analyze the research trends and frontiers in the field of groundwater-lake interaction, we conducted a comprehensive review the relevant papers from the Web of Science (WOS) database. Using VOSviewer software, we mapped the developmental trajectory of research topics in the field. Core papers from both WOS and the China National Knowledge Infrastructure (CNKI) were analyzed to systematically summarize prominent topics, research tools, and existing gaps. Based on the historical development of the field, future trends were also predicted.
Progress
Our analysis identified three successive developmental stages in this field, including the individualism stage, the reductionism stage, and the holism stage. Current hot research topics focus on water exchange, solute transport, and ecosystem mutual feedback mechanisms. Several key challenges remain, such as the spatiotemporal heterogeneity of groundwater-lake interactions, biogeochemical processes at the groundwater-lake interface, and the delayed impact of aquifers on lake ecological restoration. The primary research methods are stable isotopes, radioisotopes, temperature tracing, remote sensing, and numerical modelling. However, variations in data accuracy and spatial coverage continue to pose challenges for the practical application of these techniques.
Conclusions and Prospects
In the future, this field will enter a fourth stage characterized by big data. At this stage, it is essential to integrate diverse technological approaches, with an emphasis on using big data for high-precision monitoring to improve the characterization of dynamic groundwater-lake interactions. Additionally, multidimensional inversion models of element migration should be developed, and enhanced data mining techniques should be applied at the interface to more accurately quantify solute transport flux across the groundwater-lake interface. Finally, fostering interdisciplinary collaboration and establishing a digital ecological framework will be essential to support research on the reciprocal interactions between groundwater and lake ecosystems, promoting sustainable development and environmental protection.
- groundwater-lake interaction /
- groundwater and surface water interaction /
- lake ecological restoration /
- VOSviewer
注释:

所有作者声明不存在利益冲突。

HTML全文

图 1 地下水与湖泊交互作用研究的主题关键词共现图

area.面积; basin.流域; catchment.集水区; climate.气候; climate-change.气候变化; contamination.污染; dynamics.动态; eutrophication.富营养化; evaporation.蒸发; evapotranspiration.蒸发蒸腾; evolution.演变; flux.通量; groundwater flow.地下水流; groundwater quality.地下水水质; groundwater recharge.地下水补给; groundwater-lake interaction.地下水与湖泊交互作用; impact.影响; irrigation.灌溉; lacustrine groundwater discharge.湖底地下水排泄; long-term.长期的; nitrogen.氮; nutrients.营养成分; origin.起源; patterns.模式; phosphorus.磷; quality.质量; region.区域; resources.资源; runoff.径流; salinity.含盐量; scale.尺度; solute transport.溶质运移; system.系统; transport.传输; uncertainty.不确定性; variability.变化性; water management.水资源管理; water quality.水质; water-rock interaction.水岩相互作用; zone.区域

Figure 1. Keywords co-occurrence map of research topics in field of groundwater-lake interaction

下载: 全尺寸图片幻灯片

图 2 地下水与湖泊交互作用研究的研究手段关键词共现图

arsenic.砷; chemistry.化学; chloride.氯化物; environmental isotopes.环境同位素; equation.方程; fluoride.氟化物; fractionation.分馏; geochemistry.地球化学; gas-exchange.气体交换; geochemical evolution.地球化学进程; geometry.几何; hydrogen isotope.氢同位素; hydrogeochemistry.水文地球化学; hydrogeology.水文地质学; hydrology.水文学; indicators.指示剂; meter.量计; mass-balance.质量平衡; model.模型; modflow.modflow模型; numerical modeling.数值模拟; oxidation.氧化作用; oxygen-18.¹⁸O; radium.镭; radon.氡; rates.率; remote sensing.遥感技术; seepage meter.渗流计; simulation.模拟; stable-isotope.稳定同位素; strontium.锶; strontium isotope.锶同位素; swat.swat模型; temperature.温度; tracer.示踪剂; tritium.氚; water budget.水均衡; water chemistry.水化学

Figure 2. Keywords co-occurrence map of research methods in field of groundwater-lake interaction

下载: 全尺寸图片幻灯片

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