共查询到19条相似文献,搜索用时 131 毫秒
1.
地下水资源是水资源的重要组成部分,随着经济社会的发展,很多地区地下水超采严重,利用地表水回补地下水成为保护地下水资源的重要手段。通过对朱庄水库水源条件以及下游河道的地质构造、水文地质条件和百泉泉域水资源的供需现状与发展趋势等进行分析后,认为利用朱庄水库放水回补百泉泉域地下水从条件上及经济上是可行的。 相似文献
2.
黑河流域中西部子水系水资源分布特征研究 总被引:13,自引:3,他引:10
根据研究区的气象、水文、地质和冰川等资料,结合野外调查,研究了黑河流域中西部子水系的降水资源、冰川资源、地表水资源、地下水资源、水资源总量及其时空分布特征.山区水资源主要由祁连山南部的降水、冰雪融水等形式补给,以冰川、地表水、地下基流形式存在,冰川融水补给量为0.5532×108m3,地表水资源量为11.64×108m3,出山口基流量为5.264×108m3.河流进入山前平原后,地表水与地下水多次重复转化,南盆地地下水资源量为8.74×108m3,北盆地地下水资源量为2.06×108m3.中游耗水量的增加,加剧了中游和下游地区用水矛盾.对河流水质现状进行了分析评价,中、下游受生活污水、工业废水、农业退水的影响,河流水质较差.随着张掖市节水型社会建设和黑河流域综合治理的逐步推进,黑河流域中西部子水系的水资源问题日趋突出,研究水资源的分布特征,可为区域水资源的管理调度、可持续利用提供科学的决策依据. 相似文献
3.
柴达木盆地鱼卡河流域水资源开发利用与生态保护 总被引:2,自引:0,他引:2
鱼卡河流经2个次级断陷盆地,流域地表水资源总量为10 236.58×104 m3;地下水资源总量为17 764.55×104 m3。其中鱼卡盆地地表水资源量为10 123.06×104 m3,地下水量为6 967.85×104 m3;马海盆地地表水资源量为9 145.44×104 m3,地下水量为10 796.7×104 m3。鱼卡盆地地下水开采量为226.3×104 m3,占地下水资源量3.2%;马海盆地地下水开采量为619.8×104 m3,占地下水资源量5.7%。通过对流域地下水资源利用研究表明,随着流域地下水资源开发力度加大,下游出现了地下水资源短缺,造成生态环境恶化。例如,流域地下水不能得到合理开发利用,将进一步加剧下游生态环境更加恶化,破坏生态平衡。因此,合理开发利用流域地下水资源,是关系到流域下游工农业可持续发展的主要问题。 相似文献
4.
近三十年黑河中下游盆地地下水资源变化特征与演变趋势分析 总被引:3,自引:1,他引:2
根据1980~2005年地下水观测资料,对黑河流域中游张临高盆地与下游额济纳绿洲地下水资源变化特征及未来演变趋势进行了分析和预测。结果显示,近几十年来黑河流域中下游盆地地下水资源的变化过程主要分两个阶段。2000年黑河实施调水之前,中游盆地地下水资源主要受地表径流和阶段性土地开发利用的影响,出山径流与地下水资源的关系相对稳定,下游盆地地下水资源受中游用水的影响十分明显;从2000年实施调水后,中游盆地地下水资源与出山径流的关系发生了变化,中游盆地地下水平均水位持续下降,地下水资源量呈减少趋势,而下游额济纳旗盆地由于流入地表水数量增加,相应对地下水的补给量也增大,地下水水位则有不同程度的上升。为此,建议在水资源的利用中,应当充分利用地表水、地下水多次转化过程,最大限度地提高水资源的总体利用率。 相似文献
5.
在滨海地区地下水形成过程的研究中,通常运用如下理想模式(图1)。含水层由陆向海伸展,上游在山前开启,接受大气降水、地表水和附近浅层地下水补给(统称为陆源补给)。在含水层内形成地下迳流向下游运动。含水层末端向海开启,地下水向海排泄。此模 相似文献
6.
40 多年来,我国西北地区大规模的地下水开发利用造成了部分地区地下水水位持续下降甚至泉水干涸,部分地区地下水仍能维持动态稳定,判断这类地区水资源开发利用是否具有可持续性是必须解决的重大科学问题。以黑河流域中游盆地作为研究对象,采用MK检验和连续小波分析等方法,分析长时间序列地下水水位数据的变化特点,研究区域地下水动态特征;结合区域水文地质条件,综合划分黑河流域中游盆地地下水补排平衡区与非平衡区;利用克里金插值法估算1990—2020 年盆地含水层对水资源的调节水量,并评价不同动态平衡区的调蓄能力。结果显示,黑河流域中游盆地地下水水位动态类型有:水文型、水文-开采型、开采型和蒸发-开采型4种长周期动态稳定型,过量开采型或上游过度引用地表水型2 种长周期持续下降型。黑河-梨园河倾斜平原、酒泉盆地和黑河中游下段侵蚀堆积平原的大厚度含水层是黑河流域中游盆地的地下水补排平衡区,其在1990—2001 年共输出地下水12.06×108 m3,2001—2020年共储存地下水9.06×108 m3。大厚度含水层为地下水的长周期调蓄提供了充足的空间,在合理控制开采量的前提下,该类含水层的天然调蓄能力可满足生产生活和下游生态用水需要。盆地地下水补排非平衡区,如黑河以东诸河倾斜平原、盐池盆地和榆木山山前诸小河流域等地区,目前的地下水开发利用方式和强度是不可持续的,应适当减少地下水开采量,调节盆地上游的引水量和开采量,抑制地下水资源枯竭。本研究成果可为西北干旱内陆地区水资源管理和持续开发利用提供参考。 相似文献
7.
在系统梳理前人调查研究成果基础上,总结了西北内陆河流域主要的含水层特点,对山区、平原区和沙漠区的地下水循环特点进行了分析,着重对平原区地下水水流系统进行了讨论。由于西北内陆河流域地下水与地表水关系密切,形成了具有密切水力联系的含水层-河流系统,不论是上游开发地表水还是地下水,都会引起整个流域内地下水资源的强烈变化。地下水资源评价表明,西北内陆河流域地下水资源量为783亿m~3/a,其中平原区的地下水资源量为487亿m~3/a,山区与平原区的地下水资源重复量为199亿m~3/a,现状开采量为128亿m~3/a。地下水开发潜力分析表明,除柴达木盆地、塔里木盆地南缘等地区外,其他地区的地下水开采潜力有限,应通过提高水资源的利用效率来提高其承载能力。今后应加大(微)咸水资源化、地下水水库的调查研究,加强地下水的生态功能和生态需水量评价,为地下水资源的合理开发利用提供技术支撑。 相似文献
8.
石羊河流域水资源严重不足,过度开发利用,进入下游地区地表水量逐渐减少,地下水位普遍持续下降,导致河湖干涸、林木死亡、草场退化、沙尘暴肆虐、河流及地下水污染等一系列生态环境问题。依据流域内154眼地下水井的水质监测资料,对流域地下水水质现状进行评价,分析流域地下水质量在空间上的分布及变化状况。分析结果,整个流域受到污染,提出加强综合治理保护地下水资源已非常迫切。 相似文献
9.
黑河流域水资源及现阶段合理开发利用 总被引:6,自引:0,他引:6
黑河是我国西部较大的一条内陆河,近30多年来,由于中游地区水资源开发利用程度不断提高,使进入下游额济纳平原的地表水逐渐减少,导致下游生态环境发生恶化.为了拯救下游绿洲,改善生态环境,自1992年起对黑河中、下游用水实行计划调度,1999年开始实施国家定量分水方案.根据近几年的最新调查研究成果,计算评价了黑河流域的总水资源、地表水资源、地下水资源、地表水和地下水的利用现状及开采潜力.在此基础上,提出现阶段中游以加强引输水工程改造、提高地表水资源利用率和推广田间节水灌溉工程,发挥水利用效益;下游以适度开发利用地下水、加强地表水和地下水综合开发利用,改善生态环境.为中、下游科学分配地表水资源和合理开发利用地下水资源提供科学依据. 相似文献
10.
11.
地下水对气候变化的敏感性研究进展 总被引:4,自引:0,他引:4
地下水是人类生活、生产、生态用水的重要水源。地下水含水层的补给及其开发利用是水资源可持续开发利用与管理的重要组成部分。浅层地下水的补给主要受制于气候变异与变化。气候变化影响研究从地表水扩展至地下水不仅有利于正确地评估可利用的淡水资源,而且对于改进气候模型,更完整的描写水文循环有重要的科学意义。自21世纪以来,欧美等国开始研究不同时空尺度的地下水补给的定量估算方法,并在气候变化对水资源影响的研究中,考虑了气候变化与人类活动对地下水补给的影响。目前在我国,无论对地下水观测资料的诊断分析,或对地下水补给模型的研制都尚属空白或起步阶段。本文对当前国际上研究地下水补给以及地下水对气候变化敏感性的研究现状予以综述,目的是为了推动我国关于气候变化对水资源影响的深入研究。 相似文献
12.
Climate change has become a major global concern and threatens the security of natural environmental resources, including groundwater, especially for Cambodia. In this study, literature reviews related to climate change and groundwater resources in Cambodia were evaluated to address the impact of climate change on the groundwater environment. In Cambodia, global climate change will likely affect available water resources by driving changes in the groundwater recharge and usage pattern. Despite a general increase in the mean annual rainfall, a reduction in rainfall is anticipated during the dry season, which could lead to shortages of fresh water during the dry season. The impact of climate change on water resource environments can significantly affect national economic development. Thus, strategic management plansfor groundwater in response to climate change should be established to ensure the security of water resources in Cambodia. 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.
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
15.
地下水与环境变化研究 总被引:12,自引:2,他引:12
环境变化研究是当前国际地球科学和环境科学界最为活跃的研究领域之一。作为全球水循环的重要环节,地下水是全球环境变化的受体和信息载体。地下水及其沉积物的物理、化学指标,诸如地下水水位、宏量组分、微量组分、同位素、惰性气体等可以用作不同时间尺度上环境变化的指示剂。从地下水及其沉积物中识别和提取高分辨率的环境变化信息,实现对环境变化的预警功能是地下水科学向环境科学延伸的重要方向;而随着全球淡水资源紧缺形势不断恶化,全球环境变化、特别是全球气候变化对地下水资源的影响成为水文地质研究的新课题。 相似文献
16.
The terrestrial water cycle is the mutual transformation of surface and near-surface water, which controls the supply of fresh water resources. It is affected by human activities, solar radiation and gravity, as well as climate and environmental conditions. Inter-basin water transfer, irrigation, crop cultivation and harvesting, exploitation of groundwater water and other human activities lead to the change of spatial and temporal distribution of soil moisture, the underground water level, surface albedo, surface evaporation, as well as water and energy exchange between land surface and atmosphere. Human water use generates important feedback on the climate and changes the processes of the terrestrial water cycle significantly. The spatial and temporal distribution of precipitation in China is uneven. In addition, human activities further exacerbate the fragility of water resources and the contradiction between supply and demand, posing a serious challenge to the sustainable development of social economy. Therefore, understanding the laws and mechanisms of terrestrial water cycle change is very important for water resources utilization and human sustainable development. From the perspective of climate change and human activities, this paper summarized the impact of human activities on terrestrial water cycle and the progress of climate feedback research. It is urgent to consider the evolution of terrestrial water cycle and its climate under the dual impact of natural and human activities, and develop the large-scale land surface hydrological models and climate models with human water use, crop planting and irrigation, lateral groundwater flow. From the perspective of a fully coupled system, we need quantitatively to assess the climate feedback of human water use and its impact on the terrestrial water cycle process, and to explore its mechanism. We need to distinguish the contribution of human water activities and global climate change to the evolution of terrestrial water cycle in the context of climate change, and to propose water resources management strategies to address climate change. 相似文献
17.
I. Engelhardt R. Rausch B. Keim M. Al-Saud C. Schüth 《Environmental Earth Sciences》2013,69(2):537-555
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
18.
Water resources play an important role in supporting the economic and social development of China. The impact of climate change on water resources has become a bottleneck in this process, especially for major projects, with surface water and groundwater systems experiencing considerable impacts. The annual natural recharge of fresh groundwater is 8 840×10~8 m~3, which accounts for approximately 31% of the water resources. Groundwater is the most significant water source for many cities and energy bases, and it is also the main source acting as a buffer against extreme climate events caused by climate change. However, most of the groundwater in China buried deeply and unevenly, which increases the difficulty of investigating and exploiting this resource.This paper illustrates the general conditions of China water resources and hydrogeological hazards, such as karst sinkholes, surface subsidence, and soil salinization, caused by climate change, El Nino, La Nina, other climate events and human activities and presents the regulatory measures enacted to mitigate these issues in China.The China Geological Survey(CGS) has organized professional teams to investigate and evaluate groundwater resources and the environment since 1999. Based on these investigations, the total quantity, expected exploitable quantity and current exploited quantity of groundwater in whole China have been evaluated. In addition, an evaluation of the groundwater pollution caused by climate change throughout China and key areas has been conducted. At present, the CGS is conducting national groundwater monitoring projects and establishing regional engineering and technical measures for water resource exploitation and utilization. 相似文献
19.
Groundwater resources have considerable influences on the human population and socioeconomic development of Vietnam and the Mekong River Delta (MRD). This paper presents an overview of the relationship between climate change and groundwater in the MRD, including the challenges, strategies and technical measures. Our results showed that groundwater levels are related to other climate and hydrological variables (i.e., rainfall, river levels, etc.); therefore, the impacts of climate change on the groundwater resources of the Mekong delta are significant, especially on groundwater recharge. Based on the results of this study, it is recommended that groundwater development in the future should focus on reducing groundwater harvesting, enhancing groundwater quantity by establishing artificial works and exploiting surface water. This study suggests that the Artificial Neural Network (ANN) model is an effective tool for forecasting groundwater levels in periods of 1 month and 3 months for aquifers in the natural and tidal regime areas of the delta. 相似文献