汾河中游干流河水与大气降水和浅层地下水的转化关系

文章通过分析太原盆地汾河中游干流河水和浅层地下水的水化学和同位素资料,研究汾河干流河水与浅层地下水和大气降水之间的转化关系。结果表明:总体而言,汾河中游干流河水的补给来源以浅层地下水为主,其次为大气降水;河水在向下游径流过程中,大气降水的补给比例逐渐增大,在河流流出太原盆地附近河水主要由大气降水补给。     

新疆准噶尔盆地北部天然水的同位素研究及其应用

在对新疆准噶尔盆地北部天然水H、O同位素进行系统调查中运用同位素水文地球化学基本原理对该区不同水源类型的同位素组成进行了分析研究 ,确定了大气降水线方程和大气降水同位素高程效应 ,并对同位素蒸发效应、纬度效应和地下水形成年龄进行了探讨。这些研究成果对于阐明该区赋存铀资源的第三系砂岩含矿含水层中地下水补给来源、补给区高程和形成年龄以及论证铀成矿规律具有重要现实意义。     

渭北东部奥陶系岩溶地下水环境同位素特征分析

本文通过对渭北东部岩溶地下水环境同位素组成特征的研究,分析了大气降水、地表水、地下水三者之间的转化关系,并对研究区岩溶地下水的形成进行了初步探讨,认为大气降水是研究区岩溶地下水的补给源,地表水与地下水之间存在水力联系,地表水对地下水的补给占补给水源的74.3%.西部岩溶裸露区为岩溶水的直接补给区,其周边浅埋区为岩溶水的间接补给区,东南部的岩溶中-深埋区为岩溶水的径流排泄区.     

渭北东部奥陶系岩溶地下水环境同位素特征分

本文通过对渭北东部岩溶地下水环境同位素组成特征的研究，分析了大气降水、地表水、地下水三者之间的转化关系，并对研究区岩溶地下水的形成进行了初步探讨，认为大气降水是研究区岩溶地下水的补给源，地表水与地下水之间存在水力联系，地表水对地下水的补给占补给水源的74.3％。西部岩溶裸露区为岩溶水的直接补给区，其周边浅埋区为岩溶水的间接补给区，东南部的岩溶中-深埋区为岩溶水的径流排泄区。     

张掖盆地水文地质特征与稳定同位素研究

论述了张掖盆地地下水赋存分布特征与地下水补给、径流、排泄条件,利用水化学、同位素调查的方法,重点对张掖甘州平原区地下水水化学类型及其演化过程进行了研究。结果表明：张掖盆地由源于南部祁连山和北部龙首山的水系沉积物组成,其冲洪积平原规模、含水层富水性、导水性与地下水水化学特征等方面存在差异;同时地下水稳定同住素特征分析印证了水文地质条件的差异。祁连山前沉积物与龙首山前沉积物中地下水有着不同的补给来源和径流路径。浅层地下水和龙首山前深层承压水主要补给源为大气降水和山区河流入渗补给,祁连山前深层承压地下水系统可能有冰雪融水补给。     

河南永城市日月湖治理区水化学和氘氧同位素特征

河南省永城市日月湖生态景区治理工程在给永城市人民带来一个优美生态环境的同时,治理区地形、微地貌、水文及水文地质等条件也发生了变化,尤其是开挖后浅层地下水直接出露地表形成湖水,其水质相比之前埋藏于地下会发生改变。论文在阐述永城市日月湖景区水文地质条件的基础上,重点分析了治理区湖水、河水和浅层地下水的水化学和氘氧同位素特征。分析结果表明,湖水的水化学类型为HCO_3-SO_4-Na(Mg)型;河水水化学类型以SO_4-HCO_3-Na型为主;浅层地下水的水化学类型为HCO_3-Na-Mg型或HCO_3-Mg-Na型,个别水样中Cl-含量较高,水化学类型为HCO_3-Cl-Na(Mg,Ca)。湖水和地下水的水化学类型更接近,说明浅层地下水是湖水的重要补给来源。河水的TDS最高,浅层地下水TDS其次,湖水的TDS相对最低。研究区不同水体的氘氧同位素的分析结果说明,湖水受蒸发作用影响同位素富集;河水氘氧同位素与降水和地下水比较接近,其补给来源为大气降水和地下水;地下水除接受大气降水补给及雨季受河水补给外,还接受区域较高处的侧向径流补给,既有近源补给,也有远源补给。     

利用环境同位素信息识别鲁北平原地下水的补给特征

在野外采样的基础上,通过测试分析不同层位地下水中同位素2H 、18O、3H的特征和水化学组成,利用同位素2H、18Ｏ和3H及水化学方法识别鲁北平原地下水的补给来源,估算黄河水与地下水的转化数量,揭示黄河下游平原区的水文循环特征。研究结果表明,鲁北平原浅层地下水的主要补给源为当地的大气降水和黄河水（包括引黄灌溉和黄河水渗漏）,大气降水与黄河水所占的比例随距黄河的远近而变化。总补给量中,大气降水和黄河水的补给比例分别为86%和14%;深层地下水主要起源于古代大气降水,是在比现在寒冷的气候条件下大气降水入渗形成的。     

黑河流域水循环过程中地下水同位素特征及补给效应

通过环境同位素及其Tamers、IAEA模型应用研究表明,黑河流域水循环过程中地下水同位素特征与补给源属性和数量密切相关,具有非均一性;东部以山区降水通过出山地表径流补给为主,西部冰川雪融水和山区基岩裂隙水是主要补给源,下游区依赖中游区河水下泄状况,蒸发特征明显。东部同位素较新且地下水更新较快,西部同位素较老且地下水更新较慢;祁连山前戈壁带地下水同位素与山区河水相近,细土平原带地下水补给河水;高台一带受酒泉低氚值地下水补给影响而河水和地下水氚值都偏低;近河道带地下水年龄较新,远离河道则较老。因此,充分利用地下水与地表水之间转化规律,联合优化调控,有利于该区地下水资源可持续利用。     

九江地震台地下水氢氧稳定同位素变化特征及意义

在地震地下流体研究中,地下水补给及循环过程是重要的研究内容之一,氢氧同位素示踪技术是目前研究该过程的常用手段。通过对九江地震台2井地下水、大气降水及周边天花井水库水、马尾水高山泉水的样品进行氢氧同位素测定分析,结果表明,与降水相比地下水氢氧同位素变化更为稳定。夏半年,大气降水氢氧同位素与降水量呈显著的负相关关系,具有明显的降水量效应;冬半年,与温度成显著的正相关关系,具有明显的温度效应,地下水氢氧同位素并未表现出明显的降水效应和温度效应。氢氧同位素及过量氘揭示地下水在下渗补给前经历了明显的蒸发分馏作用,并与围岩进行~(18)O交换,δ~(18)O与δD计算的补给高程分别约为647m、440m。九江台地下水总体属于大气成因型,循环过程为较稳定的裂隙水补给形成承压自流井。     

古气候变化与地下热水中氢氧稳定同位的关系

关中盆地地下热水中氢氧稳定同位素的研究表明：研究区地下热水中氢氧稳定同位素组成变化与当地古气候变化具有良好的对应关系,古气候变化直接影响了地下热水接受补给时的氢氧稳定同位素组成。研究区地下热水的补给为更新世前古代大气降水。大约在8.2～10.2 kaB.P.和18.1～19.2 kaB.P.这两个时间段,可能是由于当时温度较低导致关中盆地地下热水补给偏少;关中盆地地下热水的补给过程受古气候的变化影响呈现非等速补给特征,可能存在一定的古地下水形成期。     

河套灌区西部浅层地下水咸化机制

浅层地下水水位埋深浅、含盐量高,是导致河套灌区土壤次生盐渍化的重要原因.以河套灌区西部地区为研究区,通过对浅层地下水的水化学和氢氧同位素特征分析以及水文地球化学模拟,探讨了灌区浅层地下水的补给来源和主控水-岩作用过程,并定量估算了蒸发作用对浅层地下水含盐量的影响.研究区内浅层地下水为弱碱性咸水,pH为7.23~8.45,总溶解性固体（total dissolved solids,TDS）变化范围为371~7 599 mg/L;随着地下水咸化程度增大,水化学类型由HCO₃-Na·Mg·Ca型向Cl-Na型过渡.引黄灌溉和大气降水是浅层地下水的主要补给来源,径流过程中浅层地下水受蒸发作用和植物蒸腾作用影响,地下水化学组分主要来源于蒸发盐溶解和硅酸盐风化水解,并受强烈的蒸发作用和离子交换作用影响.水文地球化学模拟和主成分分析结果显示,蒸发作用和岩盐溶解作用对区内浅层地下水咸化贡献最大,石膏和白云石等矿物的溶解、硅酸盐的水解、Na-Ca离子交换以及局部地形起伏对地下水咸化过程也有较大贡献.      

The impact of the geologic setting on the Quaternary aquifer,El-Tur area,Southwest Sinai,Egypt

The groundwater extracted from the unconfined Quaternary aquifer is the main source of water supply in El-Tur area. The area is bounded from the east by the elevated basement complex of Southern Sinai and from the west by El-Qabaliyat Ridge. The wadis dissecting these highlands form effective watersheds of the Quaternary aquifer. These wadis form areas of focused recharge. Recharge also occurs directly via the Quaternary sediments covering El-Qaa Plain. Subsurface lateral groundwater flow from the fractured basement contributes significant recharge to the aquifer as well. The aquifer sediment facies affect the type and quality of groundwater. In the eastern part where the aquifer is composed mainly of gravel and coarse sand with fragments of weathered basement, the Na-Cl-SO₄ water dominates. In the west where the facies change is rapid and complex, many water types arise. The base exchange index (BEX) is positive in this part reflecting the role of clay minerals in changing the water types via cation exchange. In the east where clays are insignificant in the aquifer, the BEX is negative. In the western part next to El-Qabaliyat Ridge, the wells discharging from the calcareous sand zone have low groundwater salinities compared to the wells discharging from the alluvium. In general, the groundwater salinity increases in the direction of groundwater flow from the northeast to the southwest which reflects the dissolution of aquifer sediments. The concentration relationships between the major ions on one hand and chloride on the other reflect the dissolution of calcium carbonates, precipitation of K- and Mg-bearing minerals, and cation exchange of Ca for Na on clay minerals. The hydrochemical models support these reactions. In addition, they show that the effect of evaporation on the recharge water in the western catchment is about four times its effect on the eastern recharge water which reflects the rapid recharge through the wadis draining the fractured basement. Moreover, the contribution from the eastern catchment in sample No. 23 is more than four-folds the contribution from the western recharge area. The stable isotopes (²H and ¹⁸O) show that the Quaternary aquifer is recharging from recent rainfall. However, upward leakage of Paleogene groundwater (depleted in ¹⁸O) also occurs. The groundwater level map shows strong overpumping impact especially in the areas close to El-Tur city.     

Regional groundwater flow model for Abu Dhabi Emirate: scenario-based investigation

Despite the continuous increase in water supply from desalination plants in the Emirate of Abu Dhabi, groundwater remains the major source of fresh water satisfying domestic and agricultural demands. Groundwater has always been considered as a strategic water source towards groundwater security in the Emirate. Understanding the groundwater flow system, including identification of recharge and discharge areas, is a crucial step towards proper management of this precious source. One main tool to achieve such goal is a groundwater model development. As such, the main aim of this paper is to develop a regional groundwater flow model for the surficial aquifer in Abu Dhabi Emirate using MODFLOW. Up to our knowledge, this is the first regional numerical groundwater flow model for Abu Dhabi Emirate. After steady state and transient model calibration, several future scenarios of recharge and pumping are simulated. Results indicate that groundwater pumping remains several times higher than aquifer recharge from rainfall, which provides between 2 and 5% of total aquifer recharge. The largest contribution of recharge is due to subsurface inflow from the eastern Oman Mountains. While rainfall induced groundwater level fluctuation is absent in the western coastal region, it reaches a maximum of 0.5 m in the eastern part of the Emirate. In contrast, over the past decades, groundwater levels have declined annually by 0.5 m on average with local extremes spanning from 93 m of decline to 60 m of increase. Results also indicate that a further decrease in groundwater levels is expected in most of Emirate. At other few locations, upwelling of groundwater is expected due to a combination of reduced pumping and increased infiltration of water from nonconventional sources. Beyond results presented here, this regional groundwater model is expected to provide an effective tool to water resources managers in Abu Dhabi. It will help to accurately estimate sustainable extraction rates, assess groundwater availability, and identify pathways and velocity of groundwater flow as crucial information for identifying the best locations for artificial recharge.     

基于GMS的岩溶山区三维地下水流模式识别

以高岚河东部多条支沟切割形成的连排型河间地块为研究区,基于1∶5万岩溶水文地质调查成果,利用GIS技术和径流分割,量化岩溶含水系统顶底板高程、获取入渗补给系数及地下水径流量等数据,运用三维地下水流数值模拟及粒子追踪地下水流线的方法,得出了研究区的地下水流模式。其结果表明:研究区地下水流模式主要受区域尺度的势源和势汇控制,局部的地形起伏对地下水位的影响不明显;支沟切割较深的凉伞沟、滩淤河流域,水流驱动力大,有利于局部水流系统的发育;随着东部补给高程的增加,流程逐渐增长,多发育局部水流系统,至山脊附近多发育排泄至高岚河的中间水流系统。当研究区年降雨量由中等的1 021.1 mm降为多年最低的725.5 mm时,由东部补给区排泄至高岚河的中间水流系统增加;在此降雨强度区间,不具备发育越过河间地块的中间或区域地下水流系统。      

Identification of aquifer-recharge zones and sources in an urban development area (Delhi, India), by correlating isotopic tracers with hydrological features

Recharge zones and sources in an urban setup (NCT of Delhi, India) were identified using environmental isotopes (²H, ³H, ¹⁸O); they were then correlated with hydrogeological conditions. The isotopic results showed that groundwater is being recharged by surface water during the dry season, while recharge associated with local precipitation becomes prominent during the monsoon. The effect of source-water evaporation and altitude on the isotopic characteristics of groundwater was clearly noted. A gradual increase in groundwater age, i.e. decrease in tritium content, while moving away from the river/canals/drains, suggests a degree of mixing of old-aged groundwater with relatively young recharging water. Further, to substantiate the findings of isotopic investigations, surface recharge conditions were differentiated into potential pervious (recharge prone) and impervious (recharge resistant) surfaces through mapping of potential recharge areas based on soil type and water-table depth, to depict a three-dimensional illustration of hydrogeologically mediated recharge zones of the area. The hydrogeological evidence thus obtained about the spatial distribution of permeable zones, slope and boundary conditions, aptly substantiates the isotopic findings. The study seeks its impact by correlation of the isotopic findings with the regional groundwater flow regime which has been altered by the urban development.     

环境同位素在北京平谷盆地山前侧向补给研究中的应用

利用地下水水化学和同位素测试分析成果,结合区域地质、水文地质条件研究了平谷北山山区侧向补给情况和中桥水源地地区第四系松散孔隙水和下伏岩溶水关系。结果表明：研究区第四系松散孔隙水和基岩岩溶地下水均来源于大气降水,地下水化学类型均为HCO-3-Ca2+?Mg2+ 型;平谷北山山前基岩岩溶水侧向补给平原区第四系松散孔隙水和下伏岩溶地下水;通过D值估算得到中桥水源地第四系浅层地下水的山区岩溶水侧向补给和垂向降水入渗补给比例为57：43;中桥水源地基岩岩溶水接受山区岩溶水侧向补给和第四系孔隙水垂向越流补给比例为87：13。研究成果为平谷地区地下水资源量评价和地下水动力场数值模型的建设提供了关键参数,为区域地下水的合理开采和有序回补涵养提供了科学依据。     

Numerical groundwater-flow modeling to evaluate potential effects of pumping and recharge: implications for sustainable groundwater management in the Mahanadi delta region,India

Process-based groundwater models are useful to understand complex aquifer systems and make predictions about their response to hydrological changes. A conceptual model for evaluating responses to environmental changes is presented, considering the hydrogeologic framework, flow processes, aquifer hydraulic properties, boundary conditions, and sources and sinks of the groundwater system. Based on this conceptual model, a quasi-three-dimensional transient groundwater flow model was designed using MODFLOW to simulate the groundwater system of Mahanadi River delta, eastern India. The model was constructed in the context of an upper unconfined aquifer and lower confined aquifer, separated by an aquitard. Hydraulic heads of 13 shallow wells and 11 deep wells were used to calibrate transient groundwater conditions during 1997–2006, followed by validation (2007–2011). The aquifer and aquitard hydraulic properties were obtained by pumping tests and were calibrated along with the rainfall recharge. The statistical and graphical performance indicators suggested a reasonably good simulation of groundwater flow over the study area. Sensitivity analysis revealed that groundwater level is most sensitive to the hydraulic conductivities of both the aquifers, followed by vertical hydraulic conductivity of the confining layer. The calibrated model was then employed to explore groundwater-flow dynamics in response to changes in pumping and recharge conditions. The simulation results indicate that pumping has a substantial effect on the confined aquifer flow regime as compared to the unconfined aquifer. The results and insights from this study have important implications for other regional groundwater modeling studies, especially in multi-layered aquifer systems.     

The effects of a dry sand layer on groundwater recharge in extremely arid areas: field study in the western Hexi Corridor of northwestern China

Evaporation capacity is an important factor that cannot be ignored when judging whether extreme precipitation events will produce groundwater recharge. The evaporation layer’s role in groundwater recharge was evaluated using a lysimeter simulation experiment in the desert area of Dunhuang, in the western part of the Hexi Corridor in northwestern China’s Gansu Province. The annual precipitation in the study area is extremely low, averaging 38.87 mm during the 60-year study period, and daily pan evaporation amounts to 2,486 mm. Three simulated precipitation regimes (normal, 10 mm; ordinary annual maximum, 21 mm; and extreme, 31 mm) were used in the lysimeter simulation to allow monitoring of water movement and weighing to detect evaporative losses. The differences in soil-water content to a depth of 50 cm in the soil profile significantly affected rainfall infiltration during the initial stages of rainfall events. It was found that the presence of a dry 50-cm-deep sand layer was the key factor for “potential recharge” after the three rainfall events. Daily precipitation events less than 20 mm did not produce groundwater recharge because of the barrier effect created by the dry sand. Infiltration totaled 0.68 mm and penetrated to a depth below 50 cm with 31 mm of rainfall, representing potential recharge equivalent to 1.7 % of the rainfall. This suggests that only extreme precipitation events offer the possibility of recharge of groundwater in this extremely arid area.