Hydrochemical characteristics and salinity of groundwater in the Ejina Basin, Northwestern China

A hydrochemical investigation was conducted in the Ejina Basin to identify the hydrochemical characteristics and the salinity of groundwater. The results indicate that groundwater in the area is brackish and are significantly zonation in salinity and water types from the recharge area to the discharge area. The ionic ration plot and saturation index (SI) calculation suggest that the silicate rock weathering and evaporation deposition are the dominant processes that determine the major ionic composition in the study area. Most of the stable isotope δ¹⁸O and δD compositions in the groundwater is a meteoric water feature, indicating that the groundwater mainly sources from meteoric water and most groundwater undergoes a long history of evaporation. Based on radioactive isotope tritium (³H) analysis, the groundwater ages were approximately estimated in different aquifers. The groundwater age ranges from less than 5 years, between 5 years and 50 years, and more than 50 years. Within 1 km of the river water influence zone, the groundwater recharges from recent Heihe river water and the groundwater age is about less than 5 years in shallow aquifer. From 1 km to 10 km of the river water influence zone, the groundwater sources from the mixture waters and the groundwater age is between 5 years and 50 years in shallow aquifer. The groundwater age is more than 50 years in deep confined aquifer.     

Groundwater flow modeling in the Zhangye Basin,Northwestern China

The Zhangye basin is in the middle reaches of the Heihe River, northwestern China. Heavy abstraction of groundwater since the 1970s in the area is for agricultural, industrial and drinking water supplies and has led to a substantial decline in the potentiometric surface. A three-dimensional regional numerical groundwater flow model, calibrated under transient conditions, has been developed and used to predict the drawdown for the period from 2000 to 2030 under two different groundwater management scenarios.     

Environmental isotopic and hydrochemical study of groundwater in the Ejina Basin,northwest China

The study investigates the groundwater evolution and its residence time in the Ejina Basin, northwest China according to isotope and hydrochemical analyses results. The groundwater chemistry is mainly controlled by the dissolution of halite, Glauber’s salt, gypsum, dolomite and calcite, also influenced by other processes such as evaporation, ion exchange, and deposition. Based on tritium content in atmospheric precipitation and by adopting a model with exponential time distribution function, the mean residence time of the unconfined aquifer groundwater with fairly high tritium activities (21–49 TU) is evaluated. The results show that these groundwaters have low residence time (5–120 years) and are renewable. In contrast, the deep confined groundwaters are tritium-free and radiocarbon values range from 18.3 to 26.7 pmc. According to the most commonly used ¹⁴C correction models, the radiocarbon groundwater ages were calculated which yield ages of approximately 4,087–9,364 years BP. Isotopic signatures indicate formation of deep confined groundwaters in a colder and wetter climate during the late Pleistocene and Holocene. It is suggested that long-term, rational water usage guide should be set up for the Heihe River Basin as a whole to permit a considerable discharge to the Ejina Basin.     

西北黑河额济纳盆地水资源管理研究——三维地下水流数值模拟

在大量实测资料的基础上, 建立了额济纳盆地地下水流系统饱和-非饱和三维数值模型, 对4种不同输水量情况下盆地内区域地下水位的变化趋势进行了预测, 进而提出了合理的输水方案, 黑河上中游向额济纳盆地合理的输水总量应为7.5亿m3/a, 其中通过狼心山水文站的水量不应小于5.5亿m3/a.这一方案为流域水资源的合理调配及额济纳绿洲生态环境保护和建设提供了依据.      

黑河下游额济纳盆地景观空间格局动态变化分析

基于1977、1993、2001和2005年4期Landsat遥感影像资料,选用面积、斑块数量、斑块平均大小、斑块面积标准差和面积加权平均斑块形状指数,对额济纳盆地景观空间格局的动态变化进行了分析。结果表明:乔木林面积持续减少,表现为绿洲外部及边缘的小斑块大量消失;灌木林在早期以斑块的萎缩和破碎化为主,随后因建群种演替为旱生生态型而趋于稳定,2001年后部分小斑块消失;草地在1977～1993年以小斑块的消失为主,1993～2001年以斑块的破碎化为主,2001年后斑块的团聚性增强,草地扩张;戈壁在1977～2001年斑块的破碎化程度增大,2001年后受草地恢复和巴丹吉林沙漠入侵的影响,总面积和斑块数量减少;沙地在研究期间持续扩张,1977～1993年表现为向植被的分散入侵,1993～2001年斑块的扩张和新小斑块的形成同步进行,2001年后以斑块的扩展和相互连通为主,团聚性增强。黑河输水量的变化是研究区景观空间格局动态变化的主要驱动力,在生态输水工程实施后,生态环境的恶化趋势得到了一定的扼制,但仍需采取措施提高输水的生态效果。     

Hydrochemical characteristics of groundwater in the Zhangye Basin, Northwestern China

The Zhangye Basin, located in arid northwest China, is an important agricultural and industrial center. In recent years rapid development has created an increased demand for water, which is increasingly being fulfilled by groundwater abstraction. Detailed knowledge of the geochemical evolution of groundwater and water quality can enhance understanding of the hydrochemical system, promoting sustainable development and effective management of groundwater resources. To this end, a hydrochemical investigation was conducted in the Zhangye Basin. Types of shallow groundwater in the Zhangye Basin were found to be HCO₃ ⁻, HCO₃ ⁻–SO₄ ²⁻, SO₄ ²⁻–HCO₃ ⁻, SO₄ ²⁻–Cl⁻, Cl⁻–SO₄ ²⁻ and Cl⁻ . The deep aquifer groundwater type was found to be HCO₃⁻–SO₄²⁻ throughout the entire area. Ionic ratio and saturation index calculations suggest that silicate rock weathering and evaporation deposition are the main processes that determine the ionic composition in the study area. The suitability of the groundwater for irrigation was assessed based on the US Salinity Laboratory salinity classification and the Wilcox diagram. In the study area, the compositions of the stable isotopes δ¹⁸O and δD in groundwater samples were found to range from −4.00 to −9.28‰ and from −34.0 to −65.0‰, respectively. These values indicate that precipitation is the main recharge source for the groundwater system; some local values indicate high levels of evaporation. Tritium analysis was used to estimate the ages of the different groundwaters; the tritium values of the groundwater samples varied from 3.13 to 36.62 TU. The age of the groundwater at depths of less than 30 m is about 5–10 years. The age of the groundwater at depths of 30–50 m is about 10–23 years. The age of the groundwater at depths of 50–100 m is about 12–29 years. For groundwater samples at depths of greater than 100 m, the renewal time is about 40 years.     

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     

Use of hydrogeochemistry and environmental isotopes for evaluation of groundwater in Qingshuihe Basin,northwestern China

Hydrogeochemistry and environmental isotope data were utilized to understand origin, geochemical evolution, hydraulic interconnection, and renewability of groundwater in Qingshuihe Basin, northwestern China. There are four types of groundwater: (1) shallow groundwater in the mountain front pluvial fans, originating from recent recharge by precipitation, (2) deep paleo-groundwater of the lower alluvial plains, which was formed long ago, (3) shallow groundwater in the lower alluvial plains, which has undergone evaporation during the recharge process, and (4) mixed groundwater (shallow and deep groundwater in the plain). The main water types are Na–HCO₃, which dominates type (1), and Na–SO₄, which dominates types (2) and (3). Geochemical evolution in the upper pluvial fans is mainly the result of CO₂ gas dissolution, silicates weathering and cation exchange; in the lower alluvial plains, it is related to mineral dissolution. The evaporative enrichment only produces significant salinity increases in the shallow groundwater of the lower alluvial plains. Shallow groundwater age in the upper plain is 10 years or so, showing a strong renewability. Deep groundwater ages in the lower plain are more than 200 years, showing poor renewability. In the exploitation areas, the renewability of groundwater evidently increases and the circulation period is 70–100 years.     

Application of hydrochemical signatures to delineating portable groundwater resources in Ordos Basin, China

The Ordos Basin of China encompasses Shaanxi, Gansu, and Shanxi provinces, Ningxia and Inner Mongolia autonomous regions. It lacks significant surface water resources. Among the water-bearing formations, the Luohe formation, with an area of 1.32×10⁵ km², is the most prospective aquifer. Groundwater quality data collected at 211 boreholes drilled into the Luhe formation indicate a complex distribution of groundwater chemistry. The hydrochemical properties were used to study the recharge, runoff, and discharge conditions of the groundwater in Ordos Basin and to evaluate sustainable groundwater resources. In the northern part of the basin, the hydrochemistry types and the total dissolved solids (TDS) show a clear lateral transition from SEE to NWW, indicating that the groundwater gets recharge in the northwest region and discharges in the southeast region. In the southern part of the basin, maximum TDS occurs at the center of the Malian River valley, from which the TDS decreases radially. Therefore, the groundwater in the southern basin gets recharge from the southeast and southwest regions, and the Malian River valley is the discharge zone. As a result of this research, the areas with portable groundwater were delineated. They include most of the southeast region of the Sishili Ridge, east of the Ziwu Mountain, and the southwest corner of the basin. The TDS of the groundwater in these regions is less than 1 g/l, and the hydrochemistry type is either HCO₃ or HCO₃·SO₄.     

Use of oxygen-18 isotope to quantify flows in the upriver and middle reaches of the Heihe River,Northwestern China

In recharge areas, the Heihe River flow was separated into components of ice-snowmelt and precipitation according to 14 gauging stations and to monthly hydrograph using oxygen-18. As shown by the result of the two-component mixing model, on average, 19.8% of the runoff comes from ice-snowmelt. At three stations which are closer to glaciers and with headstream of ice-snow melted water, the ice-snowmelt runoff is larger than 28% of stream water. In addition, because most of the ice-snowmelt infiltrates the groundwater, which later discharges into the river at mountain outlets, the ice-snowmelt percentage in runoff is lower than average at these stations with the elevation higher than 3,600 m. According to monthly hydrograph, the lowest percentage of ice-snowmelt in runoff is in July (6.46%), whereas during November it is the largest (26.1%). In the middle basin, the fraction of groundwater in runoff had a marked increase from 23.57% near Zhangye City to 60.28% near Gaotai City, and then a dramatic drop to 13.61% near Zhengyixia Station because of agricultural flood irrigation in Zhangye Basin.     

Groundwater Recharge and Mixing in Arid and Semiarid Regions: Heihe River Basin, Northwest China

A sound understanding of groundwater recharged from various sources occurring at different time scales is crucial for water management in arid and semi-arid river basins. Groundwater recharge sources and their geochemical evolution are investigated for the Heihe River Basin(HRB) in northwest China on the basis of a comprehensive compilation of geochemical and isotopic data. Geochemical massbalance modeling indicates that mountain-block recharge accounts for a small fraction(generally less than 5%) of the shallow and deep groundwater sustaining the oasis, whereas infiltration of rivers and irrigation water contribute most of the groundwater recharge. Dedolomitization is the primary process responsible for the changes in groundwater chemical and carbon isotope compositions from the piedmont to the groundwater discharge zone, where the dedolomitization is very likely enhanced by modern agricultural activities affecting the shallow groundwater quality. Analysis of radioactive isotopes suggests that these primary recharge sources occur at two different time scales. Radiocarbon-derived groundwater age profiles indicate a recharge rate of approximately 12 mm/year, which probably occurred during 2000–7000 years B.P., corresponding to the mid-Holocene humid period. The recharge of young groundwater on the tritium-dated time scale is much higher, about 360 mm/year in the oasis region. Infiltration from irrigation canals and irrigation return flow are the primary contributors to the increased young groundwater recharge. This study suggests that groundwater chemistry in the HRB has been influenced by the complex interaction between natural and human-induced geochemical processes and that anthropogenic effects have played a more significant role in terms of both groundwater quantity and quality.     

Land-use change and its environmental impact in the Heihe River Basin, arid northwestern China

Rapid land-use change has taken place in many arid and semi-arid regions of China over the last decade as the result of demand for food for its growing population. The Heihe River Basin, a typical inland river basin of temperate arid zone in northwestern China, was investigated to assess land-use change dynamics by the combined use of satellite remote sensing and geographical information systems (GIS), and to explore the interaction between these changes and the environment. Images were classified into six land-use types: cropland, forestland, grassland, water, urban or built-up land, and barren land. The objectives were to assess and analyze landscape change of land use/cover in Heihe River Basin over 15 years from 1987 to 2002. The results show that (1) grassland and barren land increase greatly by 22.3, and 268.2 km², respectively, but water area decreased rapidly by 247.2 km² in the upper reaches of Heihe River Basin; (2) cropland and urban or built-up land increased greatly by 174.9, and 64.6 km², respectively, but grassland decreased rapidly by 210.3 km² in the middle reaches of Heihe River Basin; and (3) barren land increased largely by 397.4 km², but grassland degraded seriously and water area decreased obviously by 313.3, and 21.7 km², respectively in the lower reaches of Heihe River Basin. These results show that significant changes in land-use occur within the whole basin over the study period and cause severe environmental degradation, such as water environmental changes (including surface water runoff change, decline of groundwater table and degeneration of surface water and groundwater quality), land desertification and salinization, and vegetation degeneracy.     

Research on hydrogen and oxygen isotopes of paleoclimate reconstruction in Nuomuhong

As a typical alluvial-proluvial fan area in the Qaidam Basin, Nuomuhong is important to the research on paleoclimate reconstruction in proluvial fan areas and basin climate change and ecological protection. This paper analyzes features of ~2H, ~3H, ~(18) O and ~(14) C isotopes in Nuomuhong and reconstructs paleoclimate in this area. According to the results: since 28 ka B.P., the ground average temperature decreases and then increases in the Qaidam watershed, reaching the lowest in 17.7 ka B.P. before increasing gradually. In the past 30 000 years, average temperature has changed ranged from 1 ℃ to 5 ℃ in this area; the lowest temperature was different from today's temperature only by 3 ℃. This shows that climate conditions and natural environment in this area have been relatively stable in the past 30 000 years.     

黑河下游额济纳盆地地下水系统划分

地下水系统的划分对于深入分析地下水的形成条件,揭示地下水的循环演化规律,进行区域地下水资源评价和规划具有重要的理论和现实意义。在论述地下水系统的有关概念及划分方法的基础上,以西北典型内流盆地黑河下游额济纳盆地为例,对地形地貌、区域地质背景及系统内含水层和水流场进行分析,从中提取依据,确定系统边界,划分地下水系统,划分出4级系统,包括2个地下水亚系统(二级系统)、4个子系统(三级系统)。     

Quantification of karst aquifer discharge components during storm events through end-member mixing analysis using natural chemistry and stable isotopes as tracers

Karst aquifer components that contribute to the discharge of a water supply well in the Classical Karst (Kras) region (Italy/Slovenia) were quantitatively estimated during storm events. Results show that water released from storage within the epikarst may comprise as much as two-thirds of conduit flow in a karst aquifer following rainfall. Principal components analysis (PCA) and end-member mixing analysis (EMMA) were performed using major ion chemistry and the stable isotopes of water (δ¹⁸O, δ²H) and of dissolved inorganic carbon (δ¹³C_DIC) to estimate mixing proportions among three sources: (1) allogenic river recharge, (2) autogenic recharge, and (3) an anthropogenic component stored within the epikarst. The sinking river most influences the chemical composition of the water-supply well under low-flow conditions; however, this proportion changes rapidly during recharge events. Autogenic recharge water, released from shallow storage in the epikarst, displaces the river water and is observed at the well within hours after the onset of precipitation. The autogenic recharge end member is the second largest component of the well chemistry, and its contribution increases with higher flow. An anthropogenic component derived from epikarstic storage also impacts the well under conditions of elevated hydraulic head, accounting for the majority of the chemical response at the well during the wettest conditions.     

Hydrogeochemistry of the Goulburn Valley region of the Murray Basin, Australia: implications for flow paths and resource vulnerability

Groundwater in the Goulburn region of the Murray Basin (Australia) contains solutes derived mainly from evapotranspiration of rainfall-derived marine aerosols, silicate dissolution, and ion exchange. ¹⁴C data indicate that groundwater in the Shepparton Formation recharges vertically across the region, whereas groundwater in the Calivil–Renmark Formation shows a greater component of lateral flow. The overall pattern of geochemical and stable isotope variations implies that long-term vertical groundwater flow into the Calivil–Renmark Formation has occurred over thousands of years. Elevated C, N, and F concentrations, together with variable Cl/Br ratios and ¹⁸O values, suggest that short-term (years to decades) flow of surface water into the Calivil–Renmark Formation also occurs locally. The high degree of vertical flow implies that the high-quality groundwater resources of the Calivil–Renmark Formation are vulnerable to surface contamination. Groundwater in both the Shepparton and Calivil–Renmark Formations yields ¹⁴C ages of up to 20 ka that imply that, overall, recharge rates are low and that, consequently, the groundwater resource in both formations could be impacted by over abstraction.

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Resumen Las aguas subterráneas de la región de Goulburn, en la cuenca del río Murray (Australia), contienen solutos procedentes principalmente de la evaporación de agua de lluvia, disolución de silicatos e intercambio iónico. Aunque la variabilidad espacial de la hidrogeoquímica es reducida, el contenido total de sales disueltas en las aguas subterráneas de la formación no confinada de Shepparton es generalmente mayor que el del acuífero inferior confinado de la Formación Calivil–Renmark. Los datos de ¹⁴C, ³H y geoquímica sugieren que la recarga del acuífero de la Formación Shepparton es por infiltración (vertical) en toda la región, mientras que la Formación Calivil–Renmark tiene una mayor proporción de aportes laterales. Sin embargo, a escala local se produce recarga vertical en la Formación Calivil–Renmark, hecho que indica que este recurso es vulnerable a la contaminación. Las aguas subterráneas de ambas formaciones tienen edades de hasta 20.000 años, según datos de ¹⁴C, lo que implica que las tasas de recarga son bajas y, en consecuencia, que podría haber impactos asociados a la sobreexplotación del recurso. Las aguas subterráneas recientes de la región se caracterizan por relaciones molares muy variables de Cl/Br (de 50 a 1.200), reflejando la química de una precipitación semiárida que se ve modificada posteriormente por disolución de halita, asociada con terrenos secos y riego con aguas salinas. Las aguas subterráneas más profundas presentan relaciones más uniformes de Cl/Br (entre 500 y 800), y probablemente reflejan que la recarga se produjo en condiciones climáticas más húmedas que las actuales.

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Résumé Les eaux souterraines de la région de Goulburn dans le bassin de Murray (Australie) contiennent des solutés provenant essentiellement de lévaporation des pluies, de la dissolution de silicates et déchanges dions. Alors quil y a peu de variations spatiales du chimisme des eaux souterraines, les concentrations en sels dissous totaux des eaux souterraines de laquifère libre de la formation de Shepparton sont en général plus élevées que celles des eaux souterraines de laquifère captif sous-jacent de la formation de Calivil-Renmark. Des données de carbone-14, de tritium et de géochimie indiquent que laquifère de la formation de Shepparton est rechargé verticalement dans toute la région, tandis que laquifère de la formation de Calivil-Renmark présente une plus forte composante découlement latéral. Toutefois, localement, il se produit une recharge verticale de laquifère de la formation de Calivil-Renmark, ce qui indique que cette ressource est vulnérable à la contamination. Les eaux souterraines des formations de Shepparton et de Calivil-Renmark présentent toutes deux des âges carbone-14 de plus de 20 ka, ce qui implique des taux de recharge très faibles et, par conséquent, que leur ressource peut être affectée par des prélèvements excessifs. Les eaux souterraines récentes dans cette région sont caractérisées par un rapport molaire Cl/Br très variable (de 50 à 1200), qui reflète le chimisme de pluies en région semi-aride modifié en conséquence par la dissolution de la halite associée à la salinité due aux terres sèches et à lirrigation. Les eaux souterraines plus profondes possèdent des rapports Cl/Br plus uniformes (de lordre de 500 à 800) et reflètent probablement des eaux de recharge sous des conditions climatiques plus humides que les conditions actuelles.

     

黑河流域下游自然资源与社会经济耦合协调响应机制研究——以阿拉善盟额济纳旗为例

为研究近40 a黑河流域下游自然资源经济系统耦合协调过程和规律,以黑河流域下游阿拉善盟额济纳旗为研究对象,根据《额济纳旗统计年鉴》(1990—2015年)自然资源和社会经济相关数据,建立指标体系,进行综合发展水平研究,通过耦合协调度模型对研究区自然资源和社会经济耦合协调度进行分析,并对2020—2030年两者的耦合协调度进行预测。结果表明: 额济纳旗自然资源综合发展水平从1990年的0.160 0提高到2015年的0.811 5,增长趋向明显; 社会经济综合发展水平从1990年的0.115 0提高到2015年的0.713 8,也呈不断上升的趋势; 二者的综合发展水平曲线变化整体相似。自然资源与社会经济耦合协调程度呈上升趋势,由1990年的“重度失调经济损益型”历经“拮抗”“发展”“磨合”阶段转变为2015年的“高度协调发展同步型”。通过灰色系统理论GM(1,1)模型,预测未来10 a两者耦合协调度将进一步提高。     

Major ion chemistry of groundwater in the extreme arid region northwest China

The Ejina Basin, located in arid northwest China, is one of the most arid areas in the world. In recent years, rapid development has created a greater demand for water which is increasingly fulfilled by groundwater abstraction. Detailed knowledge of geochemical evolution of groundwater and water quality can improve the understanding of a hydrochemical system, and promote sustainable development and effective management of groundwater resources. To this end, a hydrochemical survey was conducted in the Ejina Basin in order to identify the major hydrochemical characteristics. The results of chemical analysis indicate that groundwater in the area is brackish. The major ions, TDS, and hydrochemical types of different areas are highly variable and show an obvious zonation from the recharge area to the discharge area. Saturation index (SI), calculated according to the ionic ration plot, indicates that the gypsum-halite dissolution reactions take place under the condition of the rock weathering to some extent, and evaporation is the dominant factor to determine the major ionic composition in the study area.     

The research of groundwater flow model in Ejina Basin,Northwestern China

Water resources is a primary controlling factor for economical development and ecological environmental protection in the inland river basins of arid western China. Groundwater, as the important component of total water resources, plays a dominant role in the development of western China. In recent years, with the utilization ratio of surface water raised, the groundwater recharge rate has been reduced by surface water, and groundwater was exploited on a large-scale. This has led to the decline of groundwater levels and the degradation of eco-environments in the lower reaches of Heihe watershed, especially. Therefore, the study on the groundwater-level change in recent years, as well as simulating and predicting groundwater levels changes in the future is very significant to improve the ecological environment of the Heihe River Basin, coordinate the water contradiction, and allocate the water resources. The purpose of this study is to analyze the groundwater-level variations of the Ejina region basin on a large-scale, to develop and evaluate a conceptual groundwater model in Ejina Basin; according to the experimental observation data, to establish the groundwater flow model combining MODFLOW and GIS Software; simulated the regional hydrologic regime in recent 10 years and compared with various delivery scenarios from midstream; determined which one would be the best plan for maintaining and recovering the groundwater levels and increasing the area of Ejina Oasis. Finally, this paper discusses the possible vegetation changes of Ejina Basin in the future.     

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.