中、俄跨界含水层研究——以黑龙江—阿穆尔河中游盆地为例

跨界含水层作为全球地下水资源中的重要部分,对管理国家之间共有的珍贵水资源,建设和谐世界具有重要的意义。在有关部门和组织的配合下,在划定亚洲跨界含水层基础上,进一步研究了在中国国界上的跨界含水层,并选择中国和俄罗斯共享的黑龙江—阿穆尔河中游盆地,进行了实例研究。本项研究作为国际共享含水层资源管理计划在亚洲的第一个实例研究,将促进以中国为首的亚洲跨界含水层资源管理计划的开展。     

跨边界含水层研究

跨边界含水层作为地下水资源系统的一部分,与国际河流同样涉及国家或地区之间的利益关系。文中分析和总结了近年来对跨边界含水层研究的进展;对亚洲东部、中部和南部地下水系统进行了分析,圈定了具有重要意义的跨国界含水层9处,对这些含水层,特别是中国边界上的黑龙江—阿穆尔河平原和伊犁河谷含水层进行了评价;对中国跨省界含水层进行了初步分析。跨边界含水层问题的提出和研究,对管理国家或地区之间共有的珍贵地下水资源,建设持久和平、共同繁荣的和谐社会具有重要的意义。     

浅析跨界含水层研究

跨界含水层地下水资源同跨界河流水资源一样都是世界水资源的重要组成部分,在人们生活中发挥着重要作用,人们也日益重视对跨界含水层地下水资源的研究。国际跨边界含水层资源管理(ISARM)计划中跨界含水层主要研究内容可分为自然科学、法律、社会经济、制度和环境五个方面。近年来的研究进展主要集中在跨界含水层的划分、跨界含水层法律协议的制定、跨国合作和管理及跨界含水层评估指标体系。针对我国具体情况从跨界含水层的研究、跨界含水层条款法案的制定及跨国合作三个方面对以后的研究进行展望。     

跨边界含水层问题研究

跨边界含水层作为地下水资源系统的一部分，涉及国家或地区之间的利益关系。文章分析了跨边界含水层问题，针对亚洲东部、中部和南部地下水系统，圈定了具有重要意义的跨国界含水层9处。对这些含水层，特别是我国边界上的黑龙江一阿穆尔河平原和伊犁河谷含水层进行了评价；对我国跨省界含水层进行了初步分析。研究跨边界含水层问题，对管理国家或地区之间共有的珍贵地下水资源，建设持久和平、共同繁荣的和谐社会具有重要的意义。     

岩溶区地表水与地下水资源及环境统一评价的流域边界划分研究

岩溶地区地表水流域与地下水流域边界的分异形式有三类,即:地表分水岭与地下水流域边界在平面分布上基本一致;地表分水岭超出了地下水流域边界;地下水流域边界超出了地表分水岭。岩溶区地表水与地下水耦合流域的顶界为地表水流域的水面及下垫面,底界为浅循环潜水含水层或潜水—承压含水层下伏的隔水层顶面,在大厚度岩溶含水层分布区,可以弱岩溶发育带的顶面作为底界。其中地表水与地下水两个子系统间的次级边界,为地表水流域的下垫面。结合专门调查（勘查）评价和区域调查评价的特性,提出评价单元划分的原则及方法。这有助于在新一轮自然资源调查评价中,以流域为单元系统地开展水资源及环境调查评价,实行地表水和地下水资源及环境的统一管理。      

从黑河流域地下水年龄论其资源属性

地下水资源的可持续性是当前干旱区流域水资源管理的首要问题之一 ,我国西北内陆干旱区地下水的可持续开发必须首先要了解地下水系统的更新能力 ,地下水的放射性同位素测年可以提供系统循环时间和更新能力的重要信息。本文利用地下水中放射性氚 (3H )和碳 (1 4C)测年方法 ,计算黑河流域地下水的年龄 ,进而讨论地下水的更新性。结果表明 :潜水年龄多数小于 5 0 a,具有可再生的资源的属性 ,其中山前戈壁带和张掖盆地细土平原潜水地下水年龄小于 4 0 a,为 196 3年以来补给。酒泉东盆地排泄区承压含水层中地下水的年龄为 2 338～5 5 6 9a,额济纳附近的深层承压含水层中 ,地下水的年龄为 5 4 86～ 86 30 a,地下水资源更新性较差。但是张掖盆地河流附近深层承压地下水年龄小于 5 0 a,具有一定的更新性。上述认识不仅对黑河流域水资源管理和生态环境建设具有重要意义 ,而且对西北类似的内流盆地的地下水系统的研究有着借鉴意义     

用环境同位素论区域地下水资源属性

从可持续角度提出了区域地下水资源属性的概念; 分析了含水层系统中地下水质点的时间效应; 利用大量同位素资料分析了不同区域含水层系统中的地下水资源属性和人类活动对地下水资源属性的影响.指出利用环境同位素是研究区域地下水资源属性最直接、有效的方法; 正确认识评价区域地下水资源属性对实现地下水资源可持续性具有重要意义.      

跨界含水层研究现状与展望

随着人口的激增和水资源压力的不断增大,跨界含水层在地下水利用和供水安全保障方面处于越来越重要的位置。目前,围绕跨界含水层主要开展了以下三个方面的工作:联合国教科文组织国际水文计划联合其他相关机构,对世界各主要大洲进行了跨界含水层的标示及划分工作;在总结完善相关跨界含水层法律条文的基础上,联合国国际法委员会于2008年向联合国大会上提交了跨界含水层草案条款,该项草案条款的出台对共享含水层各国开发和管理地下水具有重要的指导意义;在联合国教科文组织及其他机构的推动下,各大洲已逐步开展对跨界含水层的研究,并建立了相关的合作机构。分析表明,跨界含水层的研究需要相关国家间的进一步协商与合作。     

海河流域地下水资源保护

地下水资源在海河流域至关重要的资源。海河平原的浅层和深层含水层大面积处于严重超采状态。地下水资源的的过量开采造成了严重环境问题。为了保护地下水资源，评价了可行的技术。利用洪水和废水进行人工回灌已进行了试验。在很多地区可以应用地表回灌系统，城市地区实施深层含水层的回灌。更好地策略是减少地下水的抽取量，特别是为了减缓地面沉降和海水入侵。应该联合运用减少地下水抽水量和人工回灌，以解决地下水位持续下降和含水层恢复的问题。     

西北内陆河流域地下水循环特征与地下水资源评价

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。     

Comparison of hydrogeological characteristics between the Sanjiang Plain and the Amur River Basin

Sanjiang Plain-Amur River Basin aquifer is the aquifer shared by China and Russia, which is of great significance to water sources management for both countries, acting as a focused area by China and Russia. In this paper, the hydrogeological characteristics of the Sanjiang Plain-Amur River Basin is studied, aiming at understanding the differences as well as similarities of aquifer classification, chemical characteristics of groundwater, quantity of groundwater and groundwater evaluation methods of two countries, which will lay a solid foundation to further holistic study of the trans-boundary aquifer in the Sanjiang Plain-Amur River Basin.     

Review on transboundary aquifers in People’s Republic of China with case study of Heilongjiang-Amur River Basin

Groundwater, as a precious resource hidden underground, is an important component of the global water system. Transboundary aquifers containing substantial amount of groundwater often carry crucial ecological and social implications. Yet, it is unfortunate that transboundary aquifers have hardly been in the forefront of political and scientific discussions, and have not received due attention by policymakers. This article attempts to summarize the investigation on the eight transboundary aquifers that China shares with the neighboring countries. An overview on the groundwater resources in China, including its distribution, exploitation and challenges is also provided. Hydrogeological condition of the Heilongjiang-Amur River Basin aquifer, which is one of the eight major aquifers, is further elaborated. Cooperative activities carried out by China and Russia on monitoring and management of this aquifer are also presented.     

Asian Transboundary Aquifers Inventory and Mapping

Transboundary aquifer (TBA) is an aquifer system that exists in more than one state. As an important component of the groundwater system, proper management and rational utilization in trans-boundary aquifers are significantly important for promoting sustainable development and good-neighbor relationships. The Transboundary Aquifers will not implicate by the country’s political boundary as it follows the natural boundary lines. Within the frame work of the UNESCO''s International Hydrological Programme (IHP-VI & VII) activities for the International Shared Aquifer Resource Management (ISARM), the inventory on TBA in Asia both preliminary and detail has accomplished. Those TBAs are classified in to two types: regional and local grade. A of Asian Transboundary Aquifers Map has advanced. The updated map provides the situation of the regional TBAs identify as the actual shape. Countries with the TBAs should strengthen cooperation for coordination and joint management of groundwater resources in order to achieve sustainable use     

Groundwater status and associated issues in the Mekong-Lancang River Basin: International collaborations to achieve sustainable groundwater resources

Groundwater is an important and readily available source of fresh water in the Mekong-Lancang River Basin. With a rapid population growth and increasing human activities, an increasing number of countries in the Mekong-Lancang River Basin are experiencing depleted and degraded groundwater supplies. In transboundary river basins, such as the Mekong-Lancang River, prioritizing the use of the shared aquifer by one riparian government may affect the opportunities of other riparian governments and lead to potential water conflicts between neighboring countries. To promote the sharing of strategies and information for the sustainable and equitable use of water resources of the shared basin, international collaborative workshops on groundwater resources have been organized for all Mekong-Lancang River countries. These workshops provide an opportunity to communicate and discuss nationally sensitive issues on groundwater by the associated countries, with topics covering multiple aspects of groundwater, such as the groundwater status in the basin, quality issues, water use conflicts, hydrological information gaps, management policies and capacity building for successful water resource management. Consensus has been reached by all countries on the importance of catchment-based groundwater management and the need for close communication among the countries. Strategies for managing transboundary aquifer issues must foster international collaboration based on the regional network, influence national networks and enhance the capacity to building maps and monitoring systems based on associated databases. The sustainability of water resources cannot be achieved without the integrated involvement and contributions by multiple countries and various stakeholders. Therefore, collaborative workshops provide a great opportunity to further our understanding of the hydrologic processes of the Mekong River Basin, share the benefits of the aquifer and provide a strategy and vision for sustainable water resource management in the Mekong-Lancang River countries.     

Assessment of groundwater residence times in the pore aquifers of the River Elbe Basin

An area covering assessment of the groundwater residence times for the upper pore aquifers in the River Elbe Basin was performed. Residence times were determined by combining groundwater velocities and flow distances along each flow-path to the surface waters using a two-dimensional model approach. Groundwater velocity was calculated as a function of hydraulic conductivity, hydraulic gradient and effective yield of pore space. Flow paths were obtained by an analysis of the morphology of the groundwater table. The mean groundwater residence time in the pore aquifers of the River Elbe Basin was quantified to about 25 years. A strong temporal blurring in the different regions between less than one year and more than 250 years was obtained. For the regional groundwater management in the Elbe Basin the groundwater residence times are an important parameter, which helps to take into account the temporal dimension in the assessment of the impact of political measures aiming at the improvement of groundwater quality with regard to diffuse pollutants (e.g. nitrate).     

Modelling an inland Delta aquifer system to evolve pre-development management schemes: a case study in Upper Thamalakane River valley, Botswana, southern Africa

 Groundwater modelling studies have been found to be a potential tool in planning the pre-development management of groundwater resources in newly developing aquifer systems. One such study was attempted in Upper Thamalakane River valley, Okavango Delta, Botswana (southern Africa). There are three major aquifers separated by two aquitards in the valley portion. The top two aquifers are freshwater bearing zones and the bottom one is saline. The hydrological set-up of the basin is complex, as the groundwater flow directions are opposite in the upper-unconfined and in the lower-confined aquifers. A preliminary multilayer model was developed for this aquifer system by making use of only available data. The hydrodynamic behavior was then studied under two prediction scenarios to evolve appropriate management decisions for locating the well field (large diameter wells) in the upper aquifer by making use of induced river infiltration during the flood season. The aquifer response for variable river-flow conditions was studied and the induced river infiltration was quantified. Received: 27 August 1998 · Accepted: 8 March 1999     

黑河流域中游盆地地下水动态特征及其调蓄能力分析

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。     

化隆—循化盆地不同类型含水层组高氟地下水的分布及形成过程

天然成因的高氟地下水是世界范围内备受关注的环境问题和饮用水安全问题。前人对高氟地下水的形成过程已开展了大量研究,但是对于高原盆地复杂水文地质条件下不同类型含水层组(第四系松散层含水层、基岩裂隙或岩溶含水层以及新生代古近纪以来的碎屑岩含水层)高氟地下水的分布和形成过程尚不明确。本文以化隆—循化盆地为研究区,通过采集、测试研究区内的各类地下水样品,分析研究区内不同类型含水层中地下水的化学特征及同位素特征。结果表明,高氟地下水(1.007.73 mg/L)主要分布在沿黄河的河谷区域和巴燕低山丘陵区域的泉水和潜水中以及深部的承压水中,在垂向上高氟地下水无明显分布规律。接受黄河水入渗补给的河谷潜水中氟离子浓度较低,补给黄河的河谷潜水中氟离子浓度较高。贫钙富钠的弱碱性苏打型水有利于地下水中氟的富集。泉水和潜水中氟主要来源于萤石的溶解,而承压水中氟除了来源于萤石外,还来源于其他含氟矿物。对于潜水和第四系松散层泉水,蒸发浓缩作用促进了地下水中氟的富集。另外,阴离子竞争吸附作用、阳离子交换吸附作用是泉水(第四系松散层泉水和基岩裂隙泉水)和潜水中氟元素富集的主要原因,而承压水中氟离子浓度受竞争吸附作用影响较大,阳离子交换吸附作用影响较小。研究成果可为化隆—循化盆地低氟地下水的勘查和开发提供科学依据。     

Groundwater mining of bedrock aquifers in the Denver Basin – past,present, and future

The Denver Basin bedrock aquifer system is an important source of water for municipal and agricultural uses in the Denver and Colorado Springs metropolitan areas. The Denver area is one of the fastest growing areas in the United States with a population of 1.2 million in 1960 that has increased to over 2.4 million by 2000. This rapid population growth has produced a corresponding increase in demand for potable water. Historically, the Denver area has relied on surface water, however, in the past 10 years new housing and recreation developments have begun to rely on groundwater from the bedrock aquifers as the surface water is fully appropriated and in short supply.The Denver Basin bedrock aquifer system consists of Tertiary and Cretaceous age sedimentary rocks known as the Dawson, Denver, Arapahoe and Laramie-Fox Hills Aquifers. The number of bedrock wells has increased from 12,000 in 1985 to 33,700 in 2001 and the withdrawal of groundwater has caused water level declines of 76 m. Water level declines for the past 10 years have ranged from 3 to 12 m per year. The groundwater supplies were once thought to last 100 years but there is concern that the groundwater supplies may be essentially depleted in 10 to 15 years in areas on the west side of the basin.Extensive development of the aquifer system has occurred in the last 25 years especially near the center of the basin in Douglas and El Paso Counties where rapid urban growth continues and surface water is lacking. Groundwater is being mined from the aquifer system because the discharge by wells exceeds the rate of recharge. Concern is mounting that increased groundwater withdrawal will cause water level declines, increased costs to withdraw groundwater, reduced well yield, and reduced groundwater storage. As the long-term sustainability of the groundwater resource is in doubt, water managers believe that the life of the Denver Basin aquifers can be extended with artificial recharge, water reuse, restrictions on lawn watering, well permit restrictions and conservation measures.