The environmental state of freshwater resources in Greece (rivers and lakes)

 The dominant factor regulating Greek riverine dissolved inorganic solid concentrations is chemical weathering, which depends on catchment climate and petrography. The majority of Greek rivers are moderately polluted and only a few of them show significant human impact and an increase in pollutant concentrations over time. Due to droughts in recent years and anthropogenic influence, the mean annual riverine dissolved solid concentrations exhibit a general interannual increase and significant long-term variations in their intra-annual hydrochemical fluctuations. The shallow Greek lakes are eutrophic, while the deep ones are oligo-mesotrophic. The majority of the lakes are monomictic and show summer thermal stratification, while the shallow ones are characterized by anoxic hypolimnetic conditions. Catchment petrography is not a dominant factor in the composition of lake waters since biochemical processes prevail. The majority of Greek lakes are also moderately polluted and are characterized by phosphorous-limited photosynthesis. Received: 17 March 1997 · Accepted: 16 January 1998     

Hydrogeological properties of a complex Dinaric karst catchment: Miljacka Spring case study

Miljacka is a karst spring situated in Dalmatia, Croatia. The interpretation of the Miljacka Spring catchment area boundary has repeatedly changed in the past, and the main conclusions of previous studies were that the spring, which is located in the Krka River canyon, receives all of its water from another karst river, Zrmanja. Here, we review a new hypothesis that the Miljacka Spring receives some of its water from the Krka River. It was not possible to verify the hypothesis by solely studying the geological composition, structural–tectonic relations and tracer test results. Therefore, a hydrochemical study was performed to confirm the hypothesis. By studying the geological composition, it was found that part of the catchment area of the Krka River is built of evaporites (gypsum and anhydrite), which are different in their mineral composition than carbonates, the usual rock mass of the Dinaric karst. The hydrochemical model was made using the NETPATH-WIN and PHREEQC software packages. The mixing model results confirmed the hypothesis that the Miljacka Spring waters come from both the Zrmanja (including smaller proportion of precipitation infiltrated directly in the karst aquifer) and Krka rivers. This case study shows the great importance of the application of hydrochemical investigations in karst hydrogeology, where research is often difficult due to the complexity of the groundwater system.     

Characterization and evaluation of the factors affecting the geochemistry of groundwater in Neyveli,Tamil Nadu,India

In order to achieve a better understanding of the nature of the factors influencing ground water composition as well as to specify them quantitatively, multivariate statistical analysis (factor analysis) were performed on the hydrochemical data of this area. R-mode factor analysis was carried out on the geochemical results of the 79-groundwater samples and the factor scores were transferred to areal maps. Fundamental chemical parameters of the groundwater have been compounded together for characterizing and interpreting a few empirical hydrogeochemical factors controlling the chemical nature of water. R-mode factor analysis reveals that the groundwater chemistry of the study area reflects the influence of anthropogenic activities, silicate weathering reactions, precipitation, dissolution and subsequent percolation into the groundwater. The data have been put into few major factors and the seasonal variation in the chemistry of water has been clearly brought out by these factors. Factor scores were transferred to contour diagrams and the factor score analysis has been used successfully to delineate the stations under study with various factors and the seasonal effect on the sample stations.     

基于水化学特征的长江源区生态水文学研究进展

气候变暖背景下,冰雪、冻土剧烈消融引起的寒区径流成分改变对流域径流演变规律及水循环机制产生了深刻影响。对长江源区各水体水化学特征及其生态水文学研究进行归纳总结,主要进展包括：长江源区的大气降水的水汽来源主要受西风环流和季风环流的控制。冰雪融水的水化学特征受到消融强度、消融持续时间和新雪融水的影响,同时在冰雪融水、积雪以及冰川融水之间可能存在化学离子的交换。冻土层上水受到降水、冰雪融水、地下冰融水等的混合补给,造成水化学特征变化的随机波动。海拔在4 500 m的地区是冻土层上水水化学特征对研究区离子控制源较为敏感的区域。随着海拔高度的增加,降雨直接补给对河水中化学离子的稀释作用逐渐减弱,同时,海拔从4 500 m到5 000 m的降水对河水中离子浓度的稀释效果最大,而在海拔5 000 m以上河水主要受冰雪融水的补给,降水和消融期的变化对河水水化学的影响很小。研究结果为更系统地认知寒区下垫面变化所引起的水文效应提供科学依据,为流域水资源的合理开发利用提供决策依据。     

Groundwater quality assessment using integrated geochemical methods,multivariate statistical analysis,and geostatistical technique in shallow coastal aquifer of Terengganu,Malaysia

Extensive agricultural, residential, and industrial activities have increased demand for water supplies, which can lead to groundwater quality degradation. The integration of geochemical methods, multivariate statistical analysis, and geostatistical approaches were carried out on 169 groundwater samples to elucidate the regional factors and processes that influencing the geochemical composition of groundwater in coastal shallow aquifer of Terengganu, Malaysia. Hydrochemical modelling revealed that the abundance of Ca and Mg was contributed by carbonate and silicate weathering while higher HCO₃ and Cl were resulted from reverse ion exchange reaction. Therefore, the dominant hydrogeochemical facies of groundwater was Ca-Mg-HCO₃-Cl type. The influence of salinization resulting from seawater mixing to the groundwater was corroborated by Cl/HCO₃ ratio, which affected around 50.9% of the groundwater samples slightly or moderately. Spatial mapping using ordinary kriging found that the threat of sea water intrusion is more prominent in the major river confluence especially around Terengganu and Marang River in the northeast and Dungun and Kemaman River confluence in southeast of study area. Moreover, factor analyses concluded that salinization, anthropogenic activities, reverse ion exchange, weathering processes, agricultural impact, and seasonal variations were the factors that regulate 63% of the major ion chemistry in study area. Finally, these findings showed the importance of understanding the hydrochemical characteristics for effective utilization, aquifer protection, and prediction of changes to minimize the effects of salinization and reduce human pollution such as agriculture and urbanization. It is essential steps in order to safeguard the utilization of groundwater resources for future generations.     

伊犁河支流大西沟河水与地下水转化关系研究

开展河流和地下水转换关系研究对于区域水资源合理开发利用具有重要意义。文章以大西沟河水与地下水转换关系为目标,在分析地下水动力场的基础上,通过水化学类型、溶解性总固体(TDS)、氯离子（Cl-）等水化学以及环境同位素18O、D、T等指标作为示踪剂,分析大西沟河和地下水的转换关系和转化强度。结果表明:研究区河流和地下水化学类型主要为HCO3—Ca,水化学类型空间分布特征相似;TDS和Cl-浓度表现为先增加后下降,但地下水的变化幅度大于河水。通过对大西沟河水和地下水中的水化学和环境同位素指标对比分析,发现研究区河流与地下水之间补给排泄关系具有明显的分段性;从河流出山口到下游地区,河水和地下水之间发生了三次转化关系:在山前倾斜砾质平原区以河水入渗补给地下水为主,补给量占该段潜水径流量的56%;到了细土平原区出现地下水补给河水地段,补给源为承压水越流补给潜水后的混合水体,潜水和承压水补给比例占该段河水径流量的20.4%与58.4%;风成沙漠区河水沿途渗漏补给地下水直至河流断流。本次研究结果为建立研究区水循环演化模式和水资源合理开发利用提供了理论和技术支持。     

济南泉域岩溶水水化学特征及其成因

济南泉域水质逐年变差,查明其污染来源和影响因素,对岩溶水资源开发利用及生态环境保护具有十分重要的意义,而对包含补给径流区的全区岩溶水系统分析尚未见报道.综合运用水化学(Piper三线图、离子比例系数、相关分析)和多元统计(因子分析、聚类分析)方法分析地下水水化学特征,探讨了不同区域水质影响因素及影响强度.因子分析反映了灰岩水岩作用、工业和生活污染、白云岩水岩作用、农牧业和生活污染对水化学组分的影响,贡献率依次为33.1%、28.4%、12.0%和11.8%.分析结果表明:研究区岩溶水水质受水岩作用和人类活动的双重影响;南部补给区、西郊及其以西排泄区水质优良,主要受碳酸盐岩溶解的影响;直接补给径流区部分岩溶水受农牧业和农村生活污染的影响,NO₃-含量较高;东郊排泄区、城区及近郊开采区受工业及城镇生活污染的影响,水质较差,少数地段SO₄2-、NO₃-、TDS和总硬度超标.      

岩溶区典型工业型城市地下水水化学特征及成因机制

文章以广西柳州市岩溶地下水为研究对象,在岩溶水文地质调查和样品采集测试的基础上,采用数理统计法、水化学方法（Piper图、Gibbs图、离子比值系数,矿物饱和指数计算）、因子分析法和模糊综合评价法,分析工业型城市岩溶地下水水化学特征及形成机制,开展岩溶地下水质量评价。结果表明,研究区岩溶地下水为中-弱碱性水,Ca2+、Mg2+、HCO₃?、SO₄2?是主要的阴阳离子,水化学类型以HCO₃-Ca型和HCO₃-Ca·Mg型为主,且城区的SO₄2?型水的比例远高于非城区。区内岩溶地下水水化学组分及演化主要受水－岩作用、工业污染、城镇生活污染和农业活动等主控因素的影响,贡献率分别为31.52%、25.15%、18.12%和10.74%。其中,城区的水化学组分受人类活动的影响程度大于非城区的。矿物饱和指数表明,区内方解石和绝大多数白云石为饱和状态,而石膏和盐岩均为溶解状态。不同功能区的水化学敏感指标有差异,工业区以重金属为主,农业区以三氮为主,生活区以K+、Na+、Cl?、SO₄2?为主。研究区整体水质较好,Ⅰ－Ⅲ类水的比例高达约87.39%;但不同区域的水质差异较大,其中城区的水质较差,超标因子主要为Al、Mn、Pb、Fe、Hg;非城区的水质较好,超标因子主要为三氮。研究成果可以为工业型城市岩溶地下水污染防治提供科学依据。      

格尔木河流域水面蒸发特征及影响因素分析

水面蒸发是水均衡的重要一项,阐明其变化特征对水资源评价具有重要的指导意义。格尔木河流域是我国西北旱区典型的内陆河流域,面临水资源开发利用与水害减灾双重挑战。前人对流域内水面蒸发相关研究未考虑主控因素及空间异质性,气候变化背景下水面蒸发特征也有待进一步研究。基于格尔木河流域气象观测资料,采用时间序列分析、相关分析和多元回归分析方法,研究了流域上游山区、中游戈壁砾石带及终端尾闾湖的水面蒸发特征及其主要影响因素。结果表明:（1）流域内水面蒸发呈波动下降趋势,但蒸发量空间差异明显,上游山区近60 年蒸发量减少了183.2 mm,中游近60 年减少了1135.1 mm,下游尾闾湖近30年减少了241.7 mm;（2）流域内水面蒸发主控因素不同,上游山区主控因素为气温,中游主控因素为风速,终端尾闾湖主控因素为水域面积;（3）流域内气候变化总体呈暖湿化,与全球气候变化一致,但水面蒸发未随气温升高和降水增加而增加,呈现出“蒸发悖论”特征。研究表明,水面蒸发的空间差异性及其主控因素对旱区流域蒸发和水资源评价具有重要影响。     

祖厉河流域水体盐分空间分布特征及演化过程

运用水化学方法,通过对祖厉河这一黄河上游重要支流的多次实地考察和采样,结合区域水文地质条件,对祖厉河流域水体盐分的空间变化特征进行分析,并揭示流域水体的演化过程。结果表明,流域水体TDS普遍较高,总体以咸水为主。水中阳离子以Na~+为主,阴离子则以Cl-、SO_4~(2-)为主。水化学类型方面,源区地下水以Mg-Ca-Na-HCO_3型水为主,河水则以Na-Mg-Cl-SO_4型水为主。流域内水体盐分主要来源于阳离子交替吸附作用、上游地下水淋滤地层盐分后以泉的形式向河流排泄以及河流径流过程中侵蚀两岸高盐分土壤或含盐地层。径流过程中,当地干旱的气候环境使水体进一步蒸发浓缩,这是流域内水体TDS进一步增高的外在水化学演化过程。总之,由于多种来源的盐分,特别是源区高TDS地下水排泄、流域内强烈的土壤侵蚀以及干旱的气候条件等多重作用过程,是祖厉河TDS显著增高失去水资源功能的主要机制。     

Integrated hydrochemical assessment of the Quaternary alluvial aquifer of the Guadalquivir River, southern Spain

The alluvial aquifer of the Guadalquivir River comprises shallow Quaternary deposits located in the central-eastern part of the Province of Jaén in southern Spain, where groundwater resources are used mainly for crop irrigation in an important agricultural area. In order to establish the baseline hydrochemical conditions and processes determining the groundwater quality, groundwater and river water samples were collected as part of an integrated investigation that coupled multivariate statistical analysis with hydrochemical methods to identify and interpret the groundwater chemistry of the aquifer system. Three main hydrochemical types (Mg–Ca–HCO₃, Ca–Mg–SO₄–HCO₃–Cl and Na–Ca–Mg–Cl–SO₄) were identified. Further interpretation, using R-mode principal components analysis (PCA) conducted with 13 hydrochemical variables, identified two principal components which explain ⅔ of the variance in the original data. In combination with the hydrochemical interpretation, mineralogical analyses of the aquifer sediment together with inverse geochemical modelling using NETPATH showed that dedolomitization (calcite precipitation and dolomite dissolution driven by gypsum dissolution) is the principal hydrochemical process controlling the regional groundwater chemistry. Other processes such as silicate weathering, ion exchange, mixing between river water and groundwater, and agricultural practices also affect the groundwater chemistry.     

中国北方三流域河流—沙漠过渡带地表沉积物化学元素空间差异分析

通过对克里雅河、毛布拉格孔兑以及西拉木伦河三流域的河流-沙漠过渡带地表沉积物的7种常量氧化物以及15种微量元素进行因子分析,结果显示:三个流域之间或不同河段因子分析提取的公因子均可以概括为较稳定的铁锰矿物、较不稳定的长石类和方解石（白云石）类等硅酸盐矿物以及稳定的稀土元素和重矿物等类别;河流间因子分析结果表明,自西向东三个流域沿河地表沉积物的化学元素富集与迁移程度呈递增趋势,化学风化程度增强;流域内因子分析结果表明,自上游至下游,样点化学组成均愈变复杂,不同河段或不同河岸沉积物化学元素空间分布规律与其物源、地貌格局以及水分条件等因素有关;自河床至阶地,不同地貌单元地表沉积物化学元素呈相异的递变规律,这与在距离河道远近不同,物源、动力因素的分配不同有关。     

黄土高原典型山地-沟壑区地下水水化学特征及成因——以六盘山地区为例

为了揭示黄土高原山地-沟壑区黄土地下水水化学特征及成因,对六盘山东西两侧山区及其西部典型黄土高原山地-沟壑区进行了多次实地考察,合理选择采样点,采集了浅层地下水监测水样。对采集的样品水化学数据进行了分析,结果表明:六盘山地区浅层地下水以低TDS重碳酸盐型为主,径流途径较短,循环条件较好,保持了较好的天然淡水资源状态;而在山地-沟壑区水化学类型则复杂多样,TDS平均值达1 870mg/L,淡水资源相对匮乏。结合各类水化学图可以看出,浅层地下水和地表水的离子来源优势机制以岩石风化为主,并且在山地-沟壑区受到不同程度蒸发作用控制。通过分析地下水中的离子浓度比以及锶元素,发现六盘山区主要为补给区和径流区,山地-沟壑区则是补给区、径流区和径流滞缓区,黄土地下水可能有来自六盘山岩溶水的补给。氟离子浓度和硬度超标是影响区域内水质的最主要因素,在受蒸发作用影响较大的地区尤为突出。黄土高原地下水资源的分布状况和质量参差不齐,保护好区域内较好的淡水资源并且按照地下水分布规律进行合理的开发与宏观调控,是缓解黄土高原水资源问题的关键。     

冰川径流温度及其响应机制研究进展

在冰冻圈地区,受到积雪和冰川融水的影响,径流表现出独特的热状况,形成特有的冷水生态系统.由于大气和河流内部过程之间强烈的耦合和高敏感度,河水温度作为生态系统的重要驱动因素在冰川流域表现得尤为显著.通过对冰川径流温度特征、影响因素和热量机制响应等方面的国内外研究现状进行综述,发现冰川径流温度具有温度低、时空变化显著的特征;冰川径流温度影响因素主要有4个方面:水-气界面的热量传输、水-河道及河岸界面热量传输、径流组成、气候变化及人类活动;冰川径流热量机制的响应在河水物理化学性质方面表现为河流水质参数以及热量水分循环的影响,在河流水生生态系统方面表现为水生生态系统的分布和结构随冰川径流温度的变化而变化,且一旦超过某个阈值后,这种变化不可逆.     

鄱阳湖流域水化学特征及影响因素分析

在地球表生系统中,化学风化作用强烈改变着岩石、水体、土壤和大气成分,是元素地球化学循环的最主要驱动力。河水溶解物质主要来源于流域内岩石化学风化,同时受到降水、人类活动的影响。文中通过对鄱阳湖流域河水样品的采集和化学成分分析,结合流域地质背景,研究了河水化学成分特征及其影响因素。结果显示,与20世纪80年代相比,本区河水Cl-、SO24-所占比例显著增高,有逐渐酸化趋势;与世界上其他主要河流相比较,该区Ca2+/Na+、Mg2+/Na+、HCO3-/Na+等比值偏低,反映了较强的蒸发岩溶解及人类活动影响特征。该区河水离子特征主要由岩石风化所控制,降水对该区河水溶解物质贡献率为10.3%,农业生产活动对鄱阳湖水溶解物质贡献率为4.9%,矿山活动对饶河丰水期、枯水期离子总量贡献率分别为8.9%、14.6%。     

Trace element chemistry of major rivers in Orissa State, India

 Geochemical analyses of surface waters from rivers flowing through Orissa State, India, indicated that trace element concentrations were extremely variable and consistently higher than world river average. The Brahmani River was the most solute-rich river studied, followed by the Baitarani and Mahanadi Rivers. Although all three rivers drain similar geology, the Brahmani River catchment is heavily industrialized, and water samples collected upstream and downstream from industries indicated that anthropogenic activity directly influenced its chemical composition. Samples collected from several towns, in all three river systems, did not invariably show similar patterns, with various elements having higher dissolved concentrations upstream. Because the concentration of total solids increased downstream, this implied that some components of the sewage had effectively sequestered available elements from solution and converted them to particulate material. Although the impact of pollution is clearly recognizable in water samples collected in proximity to the anthropogenic source, there are only slight elemental accumulations in the lower reaches of the Mahanadi River, with no accumulation in the Brahmani River. Apparently for these large rivers, discharged effluent becomes rapidly diluted, while complexation and sedimentation further removes trace elements from the water column. However, in the less voluminous Baitarani River, elementar enrichment near the river's mouth suggests that in this secondary river, where dilution effects are less, the concerns over regional water quality may be more prevalent. Received: 1 April 1995 · Accepted: 30 August 1995     

雅鲁藏布江丰水期河水离子组成特征及其控制因素

为了解雅鲁藏布江丰水期河水离子组成特征及其控制因素,利用2015年采集的8个河水水样,运用数理统计、聚类分析、Piper三线图、Gibbs模型以及离子比值等方法,分析了雅鲁藏布江丰水期河水水化学特征,并探讨了其主要控制因素。结果表明：河水中阳离子以Ca²⁺、Mg²⁺为主,阴离子则以HCO₃^-和SO₄^2-为主,阴、阳离子分别约占其总量的96%和85%。河水水化学类型均为HCO₃·SO₄-Ca·Mg型。TDS含量介于202.46~371.27 mg·L^-1,均值为299.30 mg·L^-1,较世界河流平均值高。自上至下,河水水化学特征表现出一定的差异性,河水中主要离子以及TDS、TH、EC的含量沿程表现出下降的趋势,其原因主要有支流河水汇入和降水增加的稀释作用。河水水样均落在Gibbs模型图中部偏左,表明河水中主要离子化学组分主要受水岩作用控制。离子比值法分析表明研究区碳酸盐岩以及蒸发岩的风化溶解是河水水化学的主要控制因素,且存在硅酸盐类矿物的风化。     

唐山曹妃甸浅层地下水水化学特征及咸化成因

为了查明曹妃甸浅层地下水水化学及咸化成因,采集研究区河水、地下淡水、微咸水、咸水、卤水、雨水和海水等不同类型水样,对其水化学组成、离子比、Piper三线图、吉布斯图、氢氧同位素组成及14C测年结果进行了分析。结果表明：(1)曹妃甸浅层地下水包括全新世沉积层潜水和晚更新世沉积层微承压水,且非原始封存在地层中而是形成于全新世中晚期。(2)地下潜水向海方向分布有淡水、微咸水、咸水水质类型,微承压水以咸水和卤水为主要水质类型;近冲洪积扇前缘水化学特征主要受岩石风化作用控制,围填海区及河口处水化学特征受海水混合作用控制,滨海平原区水化学特征主要受蒸发/结晶作用控制。(3)曹妃甸浅层地下水咸化过程主要是晚更新世以来海侵海退时期形成海洋蒸发盐经大气降水和河水多期溶滤所致,其盐分来源于海水蒸发盐,河口及围填海区地下潜水盐分主要来源于现代海水入侵。     

不同时间段青木关岩溶地下河水化学变化主导因素分析

利用多参数水质分析仪,对典型岩溶槽谷区重庆青木关岩溶地下河出口姜家泉的月尺度、农耕期和暴雨期3个不同时间段的水化学动态变化特征进行监测,通过主成分分析法,研究这3个不同时间段水化学变化主导因素的异同。结果表明:月尺度期间,电导率、pH值和Ca~(2+)、Mg~(2+)、K~+、Na~+、HCO_3~-受雨水稀释作用,使丰水期低于枯水期;水化学变化主要受5个主成分影响,累积方差贡献率为90.75%,但其主导因素是水-岩作用。农耕期,降雨携带残余的粪肥、氮磷钾肥汇入地下河,电导率和Cl~-、NO_3~-、K~+、Na~+浓度升高;水化学变化主要受3个主成分影响,累积方差贡献率为87.81%,但其主导因素是施肥活动。暴雨期间,各离子浓度变化经过平稳期、上升期、稳定期、特殊期4个阶段。上升期,降雨对地下河影响最大,导致水-岩作用增强,电导率和Ca~(2+)、HCO_3~-浓度上升;对地表土壤和化肥的冲刷淋溶作用显著,导致Al、Fe、Cl~-、K~+、Na~+和NO_3~-浓度明显上升。水化学变化主要受4个主成分影响,累积方差贡献率为80.09%,但其主导因素是水-岩作用、地表土壤和养分流失。