新郑市浅层地下水流数值模拟及评价

通过分析新郑市水文地质条件,建立了概念模型,运用GMS软件建立三维地下水流的数值模拟模型,对研究区浅层地下水资源进行现状评价,并对2015年和2020年地下水位进行了预测.结果表明,研究区地下水水位持续下降,到2020年水位将会下降5～10 m,部分地区可能会出现开采漏斗,为了降低地下水位的下降幅度,应该调整产业结构,加强水资源的管理,提高水资源的利用率,从而减少地下水资源的开采.     

区域含水层系统结构的体视化表达及地下水位预测——以江苏省宿迁市为例

本文结合宿市区域水文地质条件的实际状况,利用GMS对宿迁市区域含水层系统结构进行了体视化表达,使建立的区域水文地质概念模型更加直观,在概念模型的基础上建立了相应的数学模型,并利用Visual MODFLOW对宿迁市不同开采条件下的地下水位变化进行了预测。结果表明：2009年末将出现两个较大的水位降落漏斗区。根据模型预测结果,提出了该区地下水合理开采的建议。     

The importance of hydrogeological and hydrological investigations in the residential area: a case study in Burdur,Turkey

Water resources in residential areas are negatively affected by floods. In addition, many aquifers are contaminated as a result of urbanization. Great damage caused during earthquakes are partly attributed to the residential pattern which ignores the potential effect of groundwater. Hydrogeological and hydrological surveys must be carried out in the residential areas to determine the interaction between water and residential development of all types.Recent hydrogeological and hydrological investigations regarding the impact of urbanization were made for the city of Burdur (Turkey). To evaluate the effect of earthquakes on groundwater, groundwater isohypse and groundwater isopach maps were prepared showing most of the buildings within the Burdur city boundaries, which are in the areas where groundwater depth is less than 10 m. This is considered a critical depth for liquefaction during an earthquake. Lowering of the groundwater table has to be considered as one of the alternatives in reducing earthquake hazards. The chemical makeup of groundwater was also determined to consider its relationship to contamination and possible effects upon the foundations. Streams flowing across the Burdur residential area formed a flooding risk. Results of the peak flow analysis can be used to design improvements for the city. Maps of the best residential development areas have been prepared by using hydrological and hydrogeological results.     

Mechanism of the water invasion of Gaoyang Iron Mine,China and its impacts on the mine groundwater environment

With the development of mining of iron deposits in China, groundwater invasion and the impacts of groundwater drainage, such as regional groundwater table lowering, overlapping cones of depression, subsidence, and water quality deterioration are environmental problems which endanger mining production and human life. Effective prevention of water invasion or timely determination of the mechanism of water bursting and rational design of drainage plans are the most urgent mining challenges. The mechanism of water invasion and the environment impacts on the groundwater system of the Gaoyang Iron Mine, China were dealt with in this paper. A systematical investigation of the hydrogeological conditions and monitoring of groundwater dynamics of the mine were completed. Results show that the limestone of the middle Ordovician System constitutes the under floor of the iron deposit. This limestone is the main source of water invasion into the mine. Groundwater dynamic equilibrium conditions are broken due to mine drainage. Water invasion and drainage have caused a serious impact on the groundwater environment of the area.     

Application of MODFLOW and geographic information system to groundwater flow simulation in North China Plain, China

MODFLOW is a groundwater modeling program. It can be compiled and remedied according to the practical applications. Because of its structure and fixed data format, MODFLOW can be integrated with Geographic Information Systems (GIS) technology for water resource management. The North China Plain (NCP), which is the politic, economic and cultural center of China, is facing with water resources shortage and water pollution. Groundwater is the main water resource for industrial, agricultural and domestic usage. It is necessary to evaluate the groundwater resources of the NCP as an entire aquifer system. With the development of computer and internet information technology it is also necessary to integrate the groundwater model with the GIS technology. Because the geological and hydrogeological data in the NCP was mainly in MAPGIS format, the powerful function of GIS of disposing of and analyzing spatial data and computer languages such as Visual C and Visual Basic were used to define the relationship between the original data and model data. After analyzing the geological and hydrogeological conditions of the NCP, the groundwater flow numerical simulation modeling was constructed with MODFLOW. On the basis of GIS, a dynamic evaluation system for groundwater resources under the internet circumstance was completed. During the process of constructing the groundwater model, a water budget was analyzed, which showed a negative budget in the NCP. The simulation period was from 1 January 2002 to 31 December 2003. During this period, the total recharge of the groundwater system was 49,374 × 10⁶ m³ and the total discharge was 56,530 × 10⁶ m³ the budget deficit was −7,156 × 10⁶ m³. In this integrated system, the original data including graphs and attribution data could be stored in the database. When the process of evaluating and predicting groundwater flow was started, these data were transformed into files that the core program of MODFLOW could read. The calculated water level and drawdown could be displayed and reviewed online.     

Assessing the influence of climate change and inter-basin water diversion on Haihe River basin,eastern China: a coupled model approach

The modeling of changes in surface water and groundwater in the areas of inter-basin water diversion projects is quite difficult because surface water and groundwater models are run separately most of the time and the lack of sufficient data limits the application of complex surface-water/groundwater coupling models based on physical laws, especially for developing countries. In this study, a distributed surface-water and groundwater coupling model, named the distributed time variant gain model–groundwater model (DTVGM-GWM), was used to assess the influence of climate change and inter-basin water diversion on a watershed hydrological cycle. The DTVGM-GWM model can reflect the interaction processes of surface water and groundwater at basin scale. The model was applied to the Haihe River Basin (HRB) in eastern China. The possible influences of climate change and the South-to-North Water Diversion Project (SNWDP) on surface water and groundwater in the HRB were analyzed under various scenarios. The results showed that the newly constructed model DTVGM-GWM can reasonably simulate the surface and river runoff, and describe the spatiotemporal distribution characteristics of groundwater level, groundwater storage and phreatic recharge. The prediction results under different scenarios showed a decline in annual groundwater exploitation and also runoff in the HRB, while an increase of groundwater storage and groundwater level after the SNWDP’s operation. Additionally, as the project also addresses future scenarios, a slight increase is predicted in the actual evapotranspiration, soil water content and phreatic recharge. This study provides valuable insights for developing sustainable groundwater management options for the HRB.     

Groundwater abstraction and contamination in Lithuania as geoindicators of environmental change

Groundwater abstraction not only affects subsurface water, but also causes changes in the hydrosphere, lithosphere, and biosphere. There are certain symptoms of these environmental changes that might be designated as geoindicators. Geoindicators related to groundwater abstraction and contamination in Lithuania have been classified into three groups related to: (1) the decline/rise of groundwater levels, (2) the deterioration of groundwater quality, and (3) the intensification of water-rock interaction. On the basis of hydrogeological and hydrological investigations carried out over many years, different environmental impacts of intensive groundwater use are demonstrated. The most important among them are the formation of depression cones, intensification of groundwater pollution, saltwater encroachment, and the intensification of karst.     

The impact of tunneling construction on the hydrogeological environment of “Tseng-Wen Reservoir Transbasin Diversion Project” in Taiwan

Groundwater flow and the associated surface water flow are potential negative factors on underground tunnels. Early detection of environmental impacts on water resources is of significant importance to planning, design and construction of tunnel projects, as early detection can minimize accidents and project delays during construction. The groundwater modeling software package Groundwater Modeling System (GMS), which supports the groundwater numerical codes MODFLOW and FEMWATER, was utilized to determine the impact of tunneling excavation on the hydrogeological environment in a regional area around the tunnel and a local hot springs area, at the “Tseng-Wen Reservoir Transbasin Diversion Project”, in Taiwan. A hydrogeological conceptual model was first developed to simplify structures related to the site topography, geology and geological structure. The MODFLOW code was then applied to simulate groundwater flow pattern for the hydrogeological conceptual model in the tunnel area. The automated parameter estimation method was applied to calibrate groundwater level fluctuation and hydrogeological parameters in the region. Calibration of the model demonstrated that errors between simulated and monitored results are smaller than allowable errors. The study also observed that tunneling excavation caused groundwater to flow toward the tunnel. No obvious changes in the groundwater flow field due to tunnel construction were observed far away in the surrounding regions. Furthermore, the FEMWATER code for solving 3-D groundwater flow problems, in which hydrogeological characteristics are integrated into a geographic information system (GIS), is applied to evaluate the impact of tunnel construction on an adjacent hot spring. Simulation results indicated that the groundwater drawdown rate is less than the groundwater recharge rate, and the change to the groundwater table after tunnel construction was insignificant for the hot spring area. Finally, the groundwater flow obtained via the GMS indicated that the hydrogeological conceptual model can estimate the possible quantity of tunnel inflow and the impact of tunnel construction on the regional and local groundwater resources regime of the transbasin diversion project.     

A regional groundwater-flow model for sustainable groundwater-resource management in the south Asian megacity of Dhaka,Bangladesh

The water resources that supply most of the megacities in the world are under increased pressure because of land transformation, population growth, rapid urbanization, and climate-change impacts. Dhaka, in Bangladesh, is one of the largest of 22 growing megacities in the world, and it depends on mainly groundwater for all kinds of water needs. The regional groundwater-flow model MODFLOW-2005 was used to simulate the interaction between aquifers and rivers in steady-state and transient conditions during the period 1981–2013, to assess the impact of development and climate change on the regional groundwater resources. Detailed hydro-stratigraphic units are described according to 150 lithology logs, and a three-dimensional model of the upper 400 m of the Greater Dhaka area was constructed. The results explain how the total abstraction (2.9 million m³/d) in the Dhaka megacity, which has caused regional cones of depression, is balanced by recharge and induced river leakage. The simulated outcome shows the general trend of groundwater flow in the sedimentary Holocene aquifers under a variety of hydrogeological conditions, which will assist in the future development of a rational and sustainable management approach.

     

北京平谷盆地地下水库建库条件分析

中国北方干旱、半干旱地区,地下水资源在供水中占主导地位。利用业已形成的地下水位降落漏斗,建立地下水库实施水资源人工调蓄,将汛期不可利用的地表雨洪水、河水和水库弃水,通过人工干预引渗补给到地下水库中,对提高区域水资源利用率和优化水资源配置都具有重大的现实意义。平谷是北京市重要的战略性后备水源地,本文以平谷盆地为例,在水文地质条件分析的基础上,从地下储水空间、调蓄水源、补给方式、输汇水条件和入渗能力,以及取水条件等方面对平谷地下水库建库条件进行了系统分析,并提出相应的人工回灌补源工程方案,为平谷地下水库建设提供设计依据。     

近50年来我国北方典型区域地下水演化特征

文章在总结中国北方地下水最新调查成果的基础上,选择西北内陆盆地、华北平原和松嫩平原为典型区,对近50年来区域地下水系统的演变特征及其影响因素进行探讨。研究发现: 我国北方盆地和平原地下水系统演化具有渐变性和突变性特征,但在不同地区存在着差异,区域地下水系统已经变得脆弱,地下水资源可持续利用向不利的方向发展。地下水补给演变表现为山前平原地带的补给能力减弱,河道补给减弱或消失,中下游农业区地下水补给强度增大,总补给量呈现减小的趋势;  其中,西北内陆盆地下水补给的减少与上游水资源利用过度、渠系防渗程度提高有关;  而华北平原和松嫩平原地下水总补给量的减少与降雨量的减少和山区河流拦蓄水量的增加有关。伴随着补给模式的改变,地下水流场演变表现为普遍出现持续性的区域地下水位下降,西北干旱区表现为山前平原地下水位快速下降、泉流量减少、溢出带下移;  华北平原和松嫩平原表现为溢出带消失、水位降落漏斗形成并发展,区域地下水流被截断,形成以降落漏斗为中心的局部水流系统。地下水化学场变化主要表现为水化学类型变化、矿化度增大,污染组分增加。自西北内陆盆地至华北平原、松嫩平原,水化学变化强度明显增加,以华北平原和松嫩平原最为明显。本文在这些认识的基础上提出了应对气候变化与人类活动双重影响下地下水演变的适应性对策,为地下水资源可持续利用提供了理论依据。     

Responses of groundwater system to water development in northern China

The increased demands on water resources in northern China have had a significant impact on groundwater systems in the last three to four decades, including reductions in groundwater recharge capacity and overall water quality. These changes limit the potential for groundwater uses in this area. This paper discusses the issues surrounding groundwater system use in the eight basins of northern China as water resources have been developed. The results demonstrate that the recharge zone has shifted from the piedmont to the agricultural area, and that the total recharge rate in the basins tended to decrease. This decrease in arid inland basins was mainly caused by both the excessive use of water in the watershed area and irrigated channel anti-seepage. In semi-arid basins, the decrease observed in the groundwater recharge rate is related to an overall reduction in precipitation and increasing river impoundment. In addition, intensive exploitation of groundwater resources has resulted in disturbances to the groundwater flow regime in arid and semi-arid inland basins. Arid inland basins demonstrated fast falling groundwater levels in the piedmont plains resulting in declines of spring flow rates and movement of spring sites to lower locations. In the semi-arid basins, i.e. the North China Plain and the Song-nen Plain, groundwater depression cones developed and intersected regional groundwater flow. The semi-arid basins of the North China Plain and the Song-nen Plain have experienced significant hydrochemical evolution of groundwater characterized by changing water type including increase of TDS and pollutants.     

Groundwater resources and development in China

Since the establishment of new China, great attention has been paid by the government to the investigation of groundwater resources. On the basis of regional hydrogeological mapping covering most parts of the territory, an overall evaluation of groundwater resources in China is about 872 billion m³/a, in which the amounts of pore water, fissure water, and karst water are calculated separately, and the consumption of groundwater is also accounted for. Much prospecting work has been carried out for the development of well irrigation as well as the urban water supply of industrial cities. This extensive work has provided a scientific basis for the rational development and utilization of groundwater resources. According to statistics, 11.3 million ha of arable land are irrigated with water from wells, and the annual exploitation of underground water has reached 40 billion m³. In 27 cities of North China, the output of groundwater reached 6.86 million m³/d, which amounted to 87% of the total water consumed. The distribution and different hydrogeological characteristics of groundwater resources in various regions are discussed in this article, including some environmental hydrogeological problems related to the exploitation and utilization of groundwater. In short, it is evident that groundwater resources play a significant role in both urban and rural water supply, and promote the development of agriculture and industries in China.     

江苏省地下水开发利用中的环境地质问题及对策

江苏省地下水在开发利用过程中,由于开采布局不合理和存在＂三集中＂以及水文环境地质条件脆弱等因素,出现水位逐年下降,并形成区域性超采漏斗,致使部分地段地下水资源枯竭、水质咸化和诱发地面沉降、地裂缝、岩溶塌陷等诸多环境地质问题。本文着重分析全省深层地下水开发利用的四个阶段、主采层区域水位降落漏斗的发展过程和因深层水超量开采诱发的水资源枯竭、水质咸化和地面沉降、地裂缝、岩溶塌陷等环境地质问题的发育特征及演化趋势,从地下水资源管理和可持续发展的角度,提出地下水资源合理利用的对策建议。     

中国冻土地下水研究现状与进展综述

冻土地下水系统不仅在寒区水文循环中扮演着重要的角色,同时也在寒区水文过程和地表过程及其科学研究中起到了集蓄、融冻和泄流等至关重要的作用。近几十年随着全球气候变暖及人类活动（寒区工程量）的增加,冻土退化趋势显著,这一过程改变了寒区的水文地质条件,导致地下水动态特征发生显著变化,从而引起一系列的生态环境变化。近些年,诸多学者通过构建水热耦合模型来研究冻土地下水的运动机理、分布状况和季节动态,促进了寒区地下水理论知识的发展,推动了寒区水文地质知识体系的进步。本文主要针对目前我国多年冻土区地下水的研究现状进行了分析、整理、归纳,为进一步研究气候变化下地下水系统的发展与演变,以及对生态环境的影响提供参考依据。     

Hydrological and hydrogeological characteristics of Wadi el Mujib catchment area,Jordan

Hydrological and hydrogeological data in the area have been verified to evaluate the availability and the potentiality of the water resources for the proposed damsites in the Wadi el Mujib catchment area, which is considered a semiarid to arid region. The quantity of the surface waters is very small compared with the surface area of the basin, however, due to the shortage of precipitation in the country and the necessity to attain socioeconomic objectives, the investigation of these waters has become more vital. The most reliable exploitation can be essentially achieved by constructing small storage dams on the suitable sites in order to benefit from the flood waters coming from the main wadis. For the above purpose, the hydrogeological and hydrological study of Wadi el Mujib catchment area was carried out, where the Wadi Mujib dam site will be constructed. The hydrogeological investigation of the groundwater was performed by constructing a groundwater contour map of the Amman-Wadi Es Sir aquifer (B2/A7) so as to verify the groundwater flow system and to determine the potentiality of the aquifer from the hydraulic parameters obtained from the pumping test analysis. The hydrological feasibility study of the dam was carried out by evaluating the water balance for a long-term period (1970 to 1990) in order to obtain reliable data that can be used to estimate the recharge to B2/A7 aquifer. In addition, a frequency analysis was performed to estimate the flood design of the reservoir area as well as the spillway at the proposed dam site.     

东北地区地下水资源可持续利用的主要问题和对策浅析

在概述东北地区自然地理和水文地质条件的基础上，从地下水供需矛盾、地下水超采及其环境效应、地下水污染等方面阐述了影响地下水资源可持续利用的主要问题，并从社会发展、科学技术、开采历史、水资源管理、立法与执法等5个层面进行了分析。针对东北地区国民经济发展对水资源的需求、目前存在的影响地下水资源可持续利用的主要问题，提出了不同地区的地下水资源勘查开发、节约用水、地下水理论研究等地下水资源的可持续利用对策，对区域宏观水资源管理具有参考价值。     

北京西山黑龙关泉域岩溶水系统边界与水文地质性质

北方岩溶水系统具有固定补给范围和资源要素,是岩溶地下水进行独立循环的基本单元,控制了岩溶水的运移富集、水化学演化特征、资源构成以及环境地质问题。开展岩溶水系统研究的首要任务是确定系统边界位置及其水文地质性质。以北京西山黑龙关泉域岩溶水系统为研究对象,采用地质学、岩溶动力学、流体动力学、水文地球化学、地球物理勘探等方法,确定黑龙关泉域岩溶水系统是由南部大石河背斜岩溶水子系统和北部百花山向斜南翼岩溶水子系统2个次级系统组成;其含水岩层分别为蓟县系铁岭组、雾迷山组和青白口系景儿峪组、奥陶系、寒武系碳酸盐岩。根据边界的水文地质性质可以划分为地表分水岭边界、地下分水岭边界、隔水边界、岩溶含水层深埋滞流性边界等类型。     

Changes of groundwater flow field of Luanhe River Delta under the human activities and its impact on the ecological environment in the past 30 years

The Luanhe River Delta is located in the center of the Circum-Bohai Sea Economic Zone. It enjoys rapid economic and social development while suffering relatively water scarcity. The overexploitation of groundwater in the Luanhe River Delta in recent years has caused the continuous drop of groundwater level and serious environmental and geological problems. This study systematically analyzes the evolution characteristics of the population, economy, and groundwater exploitation in the Luanhe River Delta and summarizes the change patterns of the groundwater flow regime in different aquifers in the Luanhe River Delta according to previous water resource assessment data as well as the latest groundwater survey results. Through comparison of major source/sink terms and groundwater resources, the study reveals the impacts of human activities on the groundwater resources and ecological environment in the study area over the past 30 years from 1990 to 2020. The results are as follows. The average annual drop rate of shallow groundwater and the deep groundwater in the centers of depression cones is 0.4 m and 1.64 m, respectively in the Luanhe River Delta in the past 30 years. The depression cones of shallow and deep groundwater in the study area cover an area of 545.32 km² and 548.79 km², respectively, accounting for more than 10% of the total area of the Luanhe River Delta. Overexploitation of groundwater has further aggravated land subsidence. As a result, two large-scale subsidence centers have formed, with a maximum subsidence rate of up to 120 mm/a. The drop of groundwater level has induced some ecological problems in the Luanhe River Delta area, such as the zero flow and water quality deterioration of rivers and continuous shrinkage of natural wetlands and water. Meanwhile, the proportion of natural wetland area to the total wetland area has been decreased from 99% to 8% and the water area from 1776 km² to 263 km². These results will provide data for groundwater overexploitation control, land subsidence prevention, and ecological restoration in plains and provide services for water resources management and national land space planning.© 2021 China Geology Editorial Office.     

Groundwater Modeling of Fractured Aquifers in Mines: The Case Study of Gavorrano (Tuscany,Italy)

In this paper, we describe the hydrogeological problems related to the closure of the mine at Gavorrano (Tuscany, Italy). The geological and geo-structural settings of the Gavorrano area affect the groundwater flow systems and their chemical composition; hence, the settings also affect the chance and modalities to rehabilitate and re-utilize these water resources. This paper reports the results of studies, analyses of existing data and the consequent implementation of preliminary numerical models with particular reference to the effects of controlled water recovery and the complex measures required for stopping dewatering. The study incorporates recent data and the available historical records in an analysis of the hydrodynamic impact of water recovery and an assessment of the consequences of water recovery for water resources restoration. The applied numerical simulations have been demonstrated to be a promising and effective tool for planning and managing the future applications of groundwater recovery in the Gavorrano mining area. Using these applications, it will be possible to implement mitigation measures and types of re-use that consider thermal, chemical and discharge features.