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1.
华北平原气候时空演变特征   总被引:1,自引:0,他引:1  
地下水是华北平原主要的供水水源,大气降水入渗补给又是该区地下水的主要补给,因此研究气候时空演变特征对于深入剖析气候变化对其地下水资源的影响具有重要意义。依据中国18个地面气候站1951—2011年逐日气候观测资料,剖析华北平原气候时空演变特征。结果表明:华北平原近60年最低气温显著升高,最高气温基本稳定,平均气温明显升高;空间上呈由西南向东北逐渐降低、由沿海向内陆增高的趋势。降水量总体呈逐渐减少趋势,空间上由山前向滨海逐渐减弱后增强;对比分析典型极端丰枯水年的降水分布特征,不同降水年空间分布差异显著。水面蒸发量整体呈下降趋势,空间上南、北部大于中部。华北平原气候总体向暖干化方向发展,两次突变主要发生在20世纪60年代中期和70年代初。气候变化和人类活动是影响地下水资源的两个重要因素,极端气候则加强了对地下水的影响。因此,定量区分气候变化与人类活动对地下水的影响是有待进一步深入探讨的问题。  相似文献   

2.
气候变化和人类活动对华北平原水资源影响分析   总被引:8,自引:3,他引:8  
华北平原是我国粮食的重要产地.地下水资源是该地区的主要供水水源,在开采量增加和气候变化的影响下,水资源问题制约着该地区的发展.特别是近些年来降水量减少、气温呈上升趋势,使本来就少的水资源更削弱了补给资源.通过对降水、蒸发、地表径流、地下水流场变化、地下水资源的系列变化分析,认为降水量减少、气温升高、人类治水工程和开采地下水等因素是造成本地区水资源减少的重要原因.  相似文献   

3.
黄淮海平原浅层地下水埋深对气候变化响应   总被引:3,自引:0,他引:3  
地下水是陆地水循环的重要组成部分,它受气候条件和植被地形及人类活动的影响.地下水埋深对气候变化的响应研究是气候变化影响研究的前沿和热点之一,对于水资源管理及其相关研究与应用具有重要意义.本文利用陆面水文模型VIC驱动统计模型RTFN开展气候变化的敏感性试验,探讨黄淮海平原地区浅层地下水埋深对气候变化的响应.研究表明,地下水埋深对降水变化的敏感程度远大于温度变化,埋深较浅区比埋深较深区敏感.在温度变化2~5℃,降水变化±15%的情景下.黄淮海平原区平均地下水埋深变化范围大致为-81~96mm.由于地下水具有自记忆性,导致埋深对降水盈余响应滞后.该地区最大的埋深变化出现在8月.  相似文献   

4.
城市化对地下水补给的影响——以石家庄市为例   总被引:4,自引:3,他引:4       下载免费PDF全文
于开宁 《地球学报》2001,22(2):175-178
城市化对地下水补给的影响对研究城市水循环、水资源供需平衡及地下水超采、防治地下水水质恶化,以及揭示两大主要地下水环境问题(地下水超采与水质恶化)之间的有机联系都具有重要意义,石家庄城市化与地下水之间的相互作用机理研究具有典型示范性,本文以石家庄市为例,在分析地下水在城市供水中的作用及其开发利用基础上,通过研究城市化影响地下水补给的变化规律,进一步探讨了城市化对地下水补给的影响机理,最终建立城市化影响下地下水补给增量的诱发机理框图,研究结果表明,城市化会导致地下水补给量的增加;地下水开采诱发产生对城市周围井场和地表水的袭夺以及城市供、排水系统渗漏所造成的新补给源的引入是城市化诱发产生地下水补给增量的重要机理。  相似文献   

5.
华北地下水古环境意义及古气候变化对地下水形成的影响   总被引:9,自引:2,他引:7  
华北地下水的同位素和化学组分受补给时期的气候影响指示了过去3.5万a的气候变化,其δ18O的变化反映出了晚更新世向全新世转变时期的气候变化和晚更新世气温的波动;而在全新世则反映了夏季风带来丰沛降水的湿度变化。据地下水14C年龄统计特征结合其它地质记录划分出了地下水的补给期。全新世以来对地下水补给有意义的补给期是6kaB.P.左右和4kaB.P.左右,而3kaB.P.左右地下水补给明显间断,钻孔土壤水ωCl变化说明3kaB.P.左右气候干旱对地下水产生重要影响,可能是后期浅部水咸化的主要时期。  相似文献   

6.
黑河流域地下水循环演化规律研究   总被引:13,自引:3,他引:13       下载免费PDF全文
大量野外调查研究表明,气候变化和人类活动对黑河流域地下水循环和更新演变具有重要影响;平原区浅层地下水主要是现代水补给,35%来自祁连山区基岩裂隙水通过地表径流转化补给,其他是降水和冰雪融水在山前戈壁带入渗补给,具有较强的更新能力;深层承压水主要形成于地质历史时期区域性补给,与现代水循环有联系;中游区人类活动是造成下游区地下水补给能力减弱、地下水水位持续下降和生态环境退化的重要因素。因此强化中游区人类活动的科学调控,是实现黑河流域地下水可持续利用和下游区生态环境有效保护的关键。  相似文献   

7.
《地下水》2015,(6)
地下水是人类生产、生活的重要供给水源,降水入渗是地下水的主要补给来源,研究降水与地下水的关系,可为区域地下水补给、蓄存、利用的合理调度提供重要依据。根据盘山县已有的降水与地下水数据分析地下水潜水埋深与降水量之间的关系,对统筹安排、合理规划地下水的开发利用及地下水生态保护有着重要意义。  相似文献   

8.
人类活动与海河平原水资源关系研究   总被引:3,自引:0,他引:3  
海河平原是华北地区的主要平原。随着山前拦蓄地表水工程的实施,地下水资源已成为该地区的主要供水水源,在开采量增加和气候变化的影响下,水资源问题制约着该地区的发展。特别是近些年来降水量减少、气温呈上升趋势,使本来就少的水资源更削弱了补给资源。通过对降水、蒸发、地表径流、地下水流场变化、地下水资源的系列变化性分析,认为降水量减少、气温升高而引起的蒸散发量增大,人类治水工程和开采地下水等因素是造成本地区水资源减少的重要条件。  相似文献   

9.
干旱区绿洲地下水位调控方法与模型研究进展   总被引:1,自引:0,他引:1  
适宜的地下水位是干旱区绿洲健康稳定发展的基础。从地下水生态水位的调控机理、调控方法、调控模型和应用实践入手,综述了干旱区绿洲地下水生态水位调控的研究进展:地表水与地下水相互转化规律是干旱区绿洲地下水生态水位调控的理论基础,掌握人类活动强烈影响下的地表水与地下水的响应关系是关键;地下水的补给、排泄和开发利用是实现地下水位调控的三个主要途径,不同调控方法在作用环节、适用性及效果方面存在显著差异;基于不同的研究重点,目前形成了以水资源配置、水循环过程和生态过程为核心的三类调控模型;建议继续深化强人类活动影响下干旱区绿洲生态水文响应机理与演变规律研究,构建基于调控措施-循环转化-响应反馈的地下水生态水位调控体系。  相似文献   

10.
吴斌  王赛  王文祥  安永会 《中国地质》2019,46(2):369-380
基于物理过程的地表-地下水耦合模型能全面、系统地刻画流域水循环过程,并为水资源管理提供详细信息。同时,未来水资源的变化趋势受到气候变化的影响显著,在未来气候情景下水资源如何变化将影响水资源管理措施。本文以黑河中游盆地为例,基于地表水-地下水耦合模型GSFLOW,评估区域水资源对气候变化的响应,预测未来气候情景(CMIP5)下区域水资源变化趋势,为西北干旱区水资源管理提供参考。研究表明:(1)GSFLOW模型能很好地模拟黑河中游盆地复杂的水循环过程。(2)在中等排放强度(RCP4.5)下,平均每年降水上升0.6 mm,温度上升0.03℃,地下水储量减少0.38亿m3;在高排放强度(RCP8.5)下,降水上升0.8 mm,温度上升0.06℃,地下水储量减少0.34亿m3。  相似文献   

11.
为了推动我国关于气候变化对地下水影响的深入研究,列举了关于气候变化对地下水影响的研究方法,包括包气带和含水层环境示踪技术,研究地下水及其沉积物的物理化学指标,地表水-地下水耦合数值模拟技术等;综述了我国华北地区(北京市、滹沱河流域、海河流域、滦河下游地区、黄淮海平原、临汾盆地、鄂尔多斯盆地、黄河下游地区、大同盆地、北方岩溶泉域)、西北地区(塔里木下游地区、三工河流域、阿克苏河绿洲、黑河流域、石羊河流域、河西走廊、巴丹吉林沙漠)和东北地区(吉林中部平原地区、三江平原)等典型区域气候变化(气温、降水、蒸发)对地下水水位、补给量与排泄量(泉流量、开采量)、水化学成分、水温、同位素组成的影响;提出了气候变化条件下合理利用和管理地下水资源的若干对策,包括减缓温室效应引起的全球气候变暖对未来地下水资源产生不利影响,定量化研究气候变化和地下水之间的相互关系,应用高新技术开展地下水资源脆弱性的研究,充分利用灌区地下含水层的调蓄作用,通过地表水与地下水的联合利用控制水盐平衡、涵养地下水源,节约农业、工业和生活用水等。  相似文献   

12.
美国Sand Hills地区地下水数值模拟及水量平衡分析   总被引:11,自引:1,他引:11       下载免费PDF全文
利用地下水数值模型MODFLOW和非饱和带水平衡模型对处于半干旱半湿润沙丘地区(Sand Hills)地下水位进行了模拟,并分析了含水层补排水量,河流与地下水补排关系,以及区域水平衡过程。揭示了独特沙丘地形和土壤特性对地下水补排量的影响。模拟结果表明,入渗率大、非饱和带厚的沙丘有利于降水入渗补给,减少了地下水蒸散发损失。加上下覆含水层具有良好的地下水储水空间,是该地区储存丰富的地下水量,以维持河流稳定流量,供给众多湖泊和湿地的原因。该研究对我国地下水资源评价和生态环境脆弱地区水资源保护具有指导意义。  相似文献   

13.
Changes in the climatic system introduce uncertainties in the supply and management of water resources. The Intergovernmental Panel on Climate Change(IPCC) predicts an increase of 2 to 4 °C over the next 100 years. Temperature increases will impact the hydrologic cycle by directly increasing the evaporation of surface water sources. Consequently, changes in precipitation will indirectly impact the flux and storage of water in surface and subsurface reservoirs(i.e., lakes, soil moisture, groundwater, etc.). In addition, increases in temperature contribute to increases in the sea level, which may lead to sea water intrusions, water quality deterioration, potable water shortages, etc. Climate change has direct impacts on the surface water and the control of storage in rivers, lakes and reservoirs, which indirectly controls the groundwater recharge process. The main and direct impact of climate change on groundwater is changes in the volume and distribution of groundwater recharge. The impact of climate change on groundwater resources requires reliable forecasting of changes in the major climatic variables and accurate estimations of groundwater recharge. A number of Global Climate Models(GCMs) are available for understanding climate and projecting climate change.These GCMs can be downscaled to a basin scale, and when they are coupled with relevant hydrological models, the output of these coupled models can be used to quantify the groundwater recharge, which will facilitate the adoption of appropriate adaptation strategies under the impact of climate change.  相似文献   

14.
The water demand in arid regions is commonly covered by groundwater resources that date back to more humid periods of the Pleistocene and Holocene. Within the investigated arid part of SE Saudi-Arabia information about climate, groundwater levels, and pumping rates are only available for regions where groundwater extractions occur at present-day. For the prediction of the impact of long-term climate changes on groundwater resources an understanding of the hydrogeological and hydrological past and the development of the aquifers is necessary. Therefore, all available information about hydrology and hydrogeology for the past 10,000 years BP were collected and compiled to a conceptual model of the aquifer development on the Arabian Peninsula since the last Ice-Age. The climatic history was displayed by changes in precipitation, temperature and recharge during the mid-S and late Holocene. The hydrogeological development is described by groundwater ages, sea level fluctuations, movement of the coastline, and the development of sabkhas. The most sensitive parameter to describe the development of aquifer system is recharge. Present-day recharge was calculated with the hydrological model system HEC-HMS accounting for current precipitation, temperature, wind, soil types, and geomorphology. With respect to changes in precipitation and temperature over the past 10,000 years the temporal and spatial variability of groundwater recharge was calculated using empirical equations valid for semi-arid and arid settings. Further inflow into the groundwater system results from surface water infiltration in wadi beds, while natural outflow from the groundwater system occurs by discharge to the Gulf, evaporation from sabkhas, and spring discharge. Backward predictions can be verified by sedimentological observations of palaeo-river systems and lakes indicating that groundwater levels reached temporarily the surface under wetter climate conditions and 14C groundwater ages displaying groundwater residence times.  相似文献   

15.

Three-dimensional transient groundwater flow and saltwater transport models were constructed to assess the impacts of groundwater abstraction and climate change on the coastal aquifer of Tra Vinh province (Vietnam). The groundwater flow model was calibrated with groundwater levels (2007–2016) measured in 13 observation wells. The saltwater transport model was compared with the spatial distribution of total dissolved solids. Model performance was evaluated by comparing observed and simulated groundwater levels. The projected rainfalls from two climate models (MIROC5 and CRISO Mk3.6) were subsequently used to simulate possible effects of climate changes. The simulation revealed that groundwater is currently depleted due to overabstraction. Towards the future, groundwater storage will continue to be depleted with the current abstraction regime, further worsening in the north due to saltwater intrusion from inland trapped saltwater and on the coast due to seawater intrusion. Notwithstanding, the impact from climate change may be limited, with the computed groundwater recharge from the two climate models revealing no significant change from 2017 to 2066. Three feasible mitigation scenarios were analyzed: (1) reduced groundwater abstraction by 25, 35 and 50%, (2) increased groundwater recharge by 1.5 and 2 times in the sand dunes through managed aquifer recharge (reduced abstraction will stop groundwater-level decline, while increased recharge will restore depleted storage), and (3) combining 50% abstraction reduction and 1.5 times recharge increase in sand dune areas. The results show that combined interventions of reducing abstraction and increasing recharge are necessary for sustainable groundwater resources development in Tra Vinh province.

  相似文献   

16.
Climate change affects not only water resources but also water demand for irrigation. A large proportion of the world’s agriculture depends on groundwater, especially in arid and semi-arid regions. In several regions, aquifer resources face depletion. Groundwater recharge has been viewed as a by-product of irrigation return flow, and with climate change, aquifer storage of such flow will be vital. A general review, for a broad-based audience, is given of work on global warming and groundwater resources, summarizing the methods used to analyze the climate change scenarios and the influence of these predicted changes on groundwater resources around the world (especially the impact on regional groundwater resources and irrigation requirements). Future challenges of adapting to climate change are also discussed. Such challenges include water-resources depletion, increasing irrigation demand, reduced crop yield, and groundwater salinization. The adaptation to and mitigation of these effects is also reported, including useful information for water-resources managers and the development of sustainable groundwater irrigation methods. Rescheduling irrigation according to the season, coordinating the groundwater resources and irrigation demand, developing more accurate and complete modeling prediction methods, and managing the irrigation facilities in different ways would all be considered, based on the particular cases.  相似文献   

17.
Anthropogenic climate change is the Earth's most serious large-scale environmental concern. While the projected changes of global temperatures, rainfall and surface water have been modelled in a sophisticated manner, the impact on groundwater resources is much less well constrained. In southeast Australia, the decrease in rainfall amount and an increase in temperature that are predicted by climate models are generally assumed to reduce the amount of recharge to the groundwater systems. However, the increase in recharge that has resulted from clearing of the native vegetation will almost certainly produce a greater impact on the groundwater system, increasing quantity and potentially improving quality. Additionally, the impact on recharge of changes to rainfall frequency rather than just total amount is not well documented. Overall our understanding of the impacts of climate change on groundwater systems is insufficiently advanced to make firm predictions. Indirect impacts of climate change, particularly the projected increased demand for groundwater or surface water to supplement surface water supplies also will have a major impact that may be greater than the direct effect of climate change.  相似文献   

18.
Increasing water demands,especially in arid and semi-arid regions,continuously exacerbate groundwater as the only reliable water resources in these regions.Samalqan watershed,Iran,is a groundwater-based irrigation watershed,so that increased aquifer extraction,has caused serious groundwater depletion.So that the catchment consists of surface water,the management of these resources is essential in order to increase the groundwater recharge.Due to the existence of rivers,the low thickness of the alluvial sediments,groundwater level fluctuations and high uncertainty in the calculation of hydrodynamic coefficients in the watershed,the SWAT and MODFLOW models were used to assess the impact of irrigation return flow on groundwater recharge and the hydrological components of the basin.For this purpose,the irrigation operation tool in the SWAT model was utilized to determine the fixed amounts and time of irrigation for each HRU(Hydrological Response Unit)on the specified day.Since the study area has pressing challenges related to water deficit and sparsely gauged,therefore,this investigation looks actual for regional scale analysis.Model evaluation criteria,RMSE and NRMSE for the simulated groundwater level were 1.8 m and 1.1%respectively.Also,the simulation of surface water flow at the basin outlet,provided satisfactory prediction(R2=0.92,NSE=0.85).Results showed that,the irrigation has affected the surface and groundwater interactions in the watershed,where agriculture heavily depends on irrigation.Annually 11.64 Mm3 water entered to the aquifer by surface recharge(precipitation,irrigation),transmission loss from river and recharge wells 5.8 Mm3 and ground water boundary flow(annually 20.5 Mm3).Water output in the watershed included ground water extraction and groundwater return flow(annually 46.4 Mm3)and ground water boundary flow(annually 0.68 Mm3).Overally,the groundwater storage has decreased by 9.14 Mm3 annually in Samalqan aquifer.This method can be applied to simulate the effects of surface water fluxes to groundwater recharge and river-aquifer interaction for areas with stressed aquifers where interaction between surface and groundwater cannot be easily assessed.  相似文献   

19.
探索变化环境下新疆平原区地下水资源量的变化趋势,是识别地下水环境问题、加强地下水资源管理的基础工作。基于水利部门历次水资源调查评价成果、水利统计资料汇编等数据,对1956—2016年新疆平原区地下水资源量变化及其影响因素进行分析,对变化原因进行探讨。结果表明:1956—2016年新疆平原区地下水资源量呈减少趋势,其中地下水天然补给量基本稳定,地表水体转化补给量持续减少;从地下水补给结构分析,渠系渗漏补给量大幅减少,导致地下水资源量减少;河道渗漏补给量增加,抵消了地下水资源量的减幅。平原区灌溉面积扩大导致的农田灌溉耗水量增大是地下水资源量减少的根本原因,人类活动对地下水资源量的影响大于气候变化。  相似文献   

20.
In hardrock terrain where seasonal streams are not perennial source of freshwater, increase in ground water exploitation has already resulted here in declining ground water levels and deteriorating its’ quality. The aquifer system has shown signs of depletion and quality contamination. Thus, to secure water for the future, water resource estimation and management has urgently become the need of the hour. In order to manage groundwater resources, it is vital to have a tool to predict the aquifer response for a given stress (abstraction and recharge). Artificial neural network (ANN) has surfaced as a proven and potential methodology to forecast the groundwater levels. In this paper, Feed-Forward Network based ANN model is used as a method to predict the groundwater levels. The models are trained with the inputs collected from field and then used as prediction tool for various scenarios of stress on aquifer. Such predictions help in developing better strategies for sustainable development of groundwater resources.  相似文献   

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