Composition and variation of major and trace elements in Croatian bottled waters

Within the framework of the Pan-European project about the geochemistry of bottled mineral waters in Europe launched in 2007 by the European Geological Surveys (EGS) Geochemistry Expert Group fourteen brands of bottled natural waters from Croatia of both mineral and spring types were evaluated for getting more coherent spatial information about the natural variation of element concentration in bottled waters found at the European market. Results of chemical analysis show that not a single one out of fourteen analyzed bottled waters from Croatia exceeds the Croatian water standards sanctioning thereby their suitability for human consumption. Also, statistical tests performed for 41 analytes (including pH and EC) clearly show that the water chemistry is in a high degree of conformity with regional geology, depending on structural, stratigraphic and, above all, lithological diversity of aquifers. Thus Dinaric and Pannonian parts of Croatia differ largely with regard to their water types: Dinaric region is completely lacking mineral water types while, on the other side, in the Pannonian region even the spring waters show stronger mineralization in comparison with their Dinaric counterparts. Typically, all natural waters from Croatia bear the bicarbonate (HCO₃) signature. However, Ca–Mg cation pair combination is characteristic of spring waters while Na–K dominates in the mineral waters.     

Hydrochemistry of aquifers in the southern Dead Sea area,southern Jordan

 The demand for water resources in the area south of the Dead Sea due to continued development, especially at the Arab Potash Company (APC) works necessitates that water quality in the area be monitored and evaluated based on the local geology and hydrogeology. The objective of this paper is to provide information on the past and present status of the main aquifers under exploitation or planned for future development. Two main aquifers are discussed: the Safi water field, presently being operated, and the Dhiraa water field, which is being developed. The aquifer developed in the Safi water field is shallow and fed by the Hasa fault system, which drains a significant portion of the Karak mountains. This aquifer seems to be well replenished within the core, where no obvious long-term degradation in water quality can be identified. However, in the low recharge areas within the distal portions of the alluvial fan, there has been a degradation in water quality with time. The degradation is caused by the dissolution of the Lisan Marl, which is present at the outskirts of the fan system, based on hydrochemistry of water in the wells. The Dhiraa field is a deep (800–950 m) aquifer drilled specifically for the extraction of brackish water present in the Kurnub aquifer. Available data indicate that there are at least three distinct water types within this field. These water types are variable in quality, and there may be potential for mixing of these waters, thus affecting the quality of the freshest waters presently available. Tritium and oxygen isotope analysis indicate that the water is old and possibly nonrenewable. Received: 24 July 1995 · Accepted: 26 September 1995     

关于水化学中几个问题的探讨

该文就水化学研究中所涉及的碳酸平衡与温度的关系、方解石等碳酸盐岩矿物溶解度与温度的关系、pH值控制下方解石、白云石的溶解产物、矿物实测溶解度大于计算溶解度、Cl-的络合物、浅海环境下形成方解石矿物、舒卡列夫水化学式的改进建议等问题进行了分析与解释,并提出一些看法、认识及建议。     

Hydrochemical appraisal of groundwater and its suitability in the intensive agricultural area of Muzaffarnagar district,Uttar Pradesh,India

Muzaffarnagar is an economically rich district situated in the most fertile plains of two great rivers Ganga and Yamuna in the Indo-gangetic plains, with agricultural land irrigated by both surface water as well as groundwater. An investigation has been carried out to understand the hydrochemistry of the groundwater and its suitability for irrigation uses. Groundwater in the study area is neutral to moderately alkaline in nature. Chemistry of groundwater suggests that alkaline earths (Ca + Mg) significantly exceed the alkalis (Na + K) and weak acids exceed the strong acids (Cl + SO₄), suggesting the dominance of carbonate weathering followed by silicate weathering. Majority of the groundwater samples (62%) posses Ca–Mg–HCO₃ type of hydrochemical species, followed by Ca–Na–Mg–HCO₃, Na–Ca–Mg–HCO₃, Ca–Mg–Na–HCO₃–Cl and Na–Ca–HCO₃–SO₄ types. A positive high correlation (r ² = 0.928) between Na and Cl suggests that the salinity of groundwater is due to intermixing of two or more groundwater bodies with different hydrochemical compositions. Barring a few locations, most of the groundwater samples are suitable for irrigation uses. Chemical fertilizers, sugar factories and anthropogenic activities are contributing to the sulphate and chloride concentrations in the groundwater of the study area. Overexploitation of aquifers induced multi componential mixing of groundwater with agricultural return flow waters is responsible for generating groundwater of various compositions in its lateral extent.     

The hydrochemical characteristics and its significance of geothermal water in both sides of large fault: Taking northern section of the Liaokao fault in north China as an example

Based on comparative analysis on hydrochemical characteristics of geothermal water in the north part of Liaokao fault, this research focuses on studying the indicative significance of hydrochemical characteristics for the formation of geothermal water. The result shows that: (1) There is no obvious hydraulic connection between the karst geothermal water (occurred in the east part of the Liaokao fault) and the sandstone geothermal water (occurred in the west part of Liaokao fault). (2) In a close hydrological environment, caused by tectonic activities, geothermal water remains longer time in reservoir, hence the water-rock interaction is more complete, with high degree of concentrations, whereas the renewable capacity of the water is weaker. (3) There is no high temperature mantle source fluid mixed in the geothermal water. Karst geothermal water occurred deep circulatory convection along Liaokao fault and its secondary fault, therefore there is deep crust source fluid added into the geothermal water, closer to the Liaokao fault, the greater affected by the deep crust fluid. However, sandstone geothermal water has weak deep circulatory convection.     

Geological characteristics and analysis of hydrothermal genesis in the Suijiang-1 well in Yunnan Province,China

The geothermal water hydrochemistry and isotopic characteristics of boreholes in the Suijiang-1 well in Yunnan Province were studied based on the actual drilling geology, regional geological structure and hydrogeological conditions. The analysis results show that the geothermal water is SO_4-Ca·Mg type, the recharge elevation is 1 381-1 646 m, the recharge source is atmospheric precipitation, the geothermal reservoir temperature is 42-45 ℃, and the geothermal water is controlled by lithology and geological structure conditions of study area. Atmospheric precipitation enters the groundwater circulation system through the surface karst form of the Wujiaobao anticline, northwest-southeast tensile faults, fissures and karst depression, and geothermal water formed through the rising deep cycle water temperature, then blocked by the double rivers' fault zone and drilling explosion.     

Temporal variations in the depth-specific hydrochemistry and sewage-related microbiology of an urban sandstone aquifer,Nottingham, United Kingdom

The temporal and spatial characteristics of groundwater recharge in urban environments remain poorly understood. Depth-specific monitoring of groundwater quality in the Triassic Sandstone underlying the city of Nottingham, UK, indicates that contamination results primarily from sewage and atmospheric sources. The temporal and depth-specific characteristics of microbial and inorganic (e.g. nitrate, chloride, sulphate) contamination over the investigation period differ significantly and reflect the contrasting transport characteristics of surface-loaded solutes and particulate microbial species (bacteria and viruses) in the Triassic Sandstone. Differences result from a variety of factors, which include microbial die-off, dilution, and the contaminant-source characteristics. Observations in this study show that low levels of microbial contamination should be expected at depth in fissured sandstone due to aquifer heterogeneities such as fissuring and the occurrence of mudstone bands, though the magnitude of this contamination will vary over time. Furthermore, urban groundwater-protection measures based on solute-transport estimates may not be applicable to microbial contamination. Electronic Publication     

北天山重点监视区水化学中短期前兆指标探索

为了实现中国地震局“九五”重点攻关项目“中短期前兆识别方法、标识体系和评价研究”提出的目标,对北天山重点监视区１９８０￣１９９７年的水化学观测进行了全时域的扫描分析,用差分求和法对资料异常进行了识别,结果表明：差分求和法能有效识别异常和提取地震中短期前兆指标,结果表明：差分求和法能有效识别异常和提取地震中短期前兆指标,用该方法检出的异常判定指标信度较高。     

Identifying trends in groundwater quality using residence time indicators: an example from the Permian aquifer of Dumfries, Scotland

The Permian sandstone and breccia aquifer of Dumfries has an important role in supplying water to the principal town in southwest Scotland. The area comprises mainly pastoral farmland with some industry and fish farming. Ongoing development of the aquifer has revealed the existence of complex groundwater flow through fractures and increasing nitrate concentrations. To further investigate these issues, the age and quality of groundwater throughout the aquifer has now been assessed using standard hydrogeochemical techniques together with CFCs and SF₆ as residence time indicators. The aquifer consists of sandstone- and breccia-dominated units: the Locharbriggs Sandstone in the east and the Doweel Breccia in the west. Groundwater throughout the aquifer is of Ca–Mg–HCO₃ type and moderately mineralised; pH is near neutral. The observed groundwater chemistry is the product of maritime rainfall modified by the dissolution of carbonate material in the breccia, sandstone and surficial deposits. CFC and SF₆ concentrations are interpreted on the basis of mixing between older (>50 years) and recent (1990s) components. Although there is generally a higher proportion of older water within the Locharbriggs Sandstone compared to the Doweel Breccia, stable isotope evidence suggests that the older water component in the interbedded sandstones of the breccia is of much greater antiquity, possibly containing an element of palaeowater. Concentrations of nitrate across the aquifer can be directly related to the amount of recent recharge. Modern groundwater contains approximately 9 mg l^–1 NO₃-N and pre-1950s groundwater has approximately 2 mg l^–1 NO₃-N. Nitrate concentrations measured at individual boreholes are explained by the relative proportions of modern and pre-1950s groundwater. If current practices continue, the concentrations of nitrate measured across the Dumfries Basin will rise as the proportion of pre-1950s groundwater diminishes.

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Resumen El acuífero de areniscas y brechas Pérmicas de Dumfries desempeña un papel importante en el abastecimiento a la ciudad principal del Sudoeste de Escocia. El área comprende sobretodo tierras de pastoreo y granjas, junto con algunas industrias y piscifactorías. El desarrollo iniciado en el acuífero ha revelado la existencia de un complicado flujo subterráneo a través de las fracturas y de un aumento progresivo en la concentración de nitrato. Con el fin de profundizar en el conocimiento de estos temas, se ha determinado la edad y calidad de las aguas subterráneas en todo el acuífero por medio de técnicas hidrogeoquímicas estándar y de indicadores del tiempo de residencia como los clorofluorcarbonados (CFCs) y el fluoruro de azufre (SF₆). El acuífero está formado por las areniscas de Locharbriggs, al Este, y las brechas de Doweel, hacia el Oeste. Las aguas subterráneas son de tipo bicarbonatadas cálcico-magnésicas y presentan una mineralización moderada, mientras que el pH es prácticamente neutro. La química de las aguas subterráneas es el resultado del aerosol marino modificado por la disolución de materiales carbonatados en las brechas, areniscas y depósitos superficiales. Las concentraciones de CFCs y SF₆ se interpretan a partir de una mezcla de aguas entre una componente antigua (más de 50 años) y una reciente (de la década de 1990). Aunque en general se da una mayor proporción de aguas antiguas en las areniscas de Locharbriggs que en las Brechas de Doweel, los isótopos estables sugieren que la componente de aguas antiguas en las intercalaciones de areniscas que aparecen en la formación de brechas es mucho más antigua, y que, posiblemente, se trate de paleoaguas. Las concentraciones de nitrato en el acuífero pueden ser relacionadas directamente con la aportación de recarga reciente. Las aguas subterráneas modernas contienen aproximadamente 9 mg l^–1 de nitrato, mientras que las aguas subterráneas anteriores a 1950 tienen unos 2 mg l^–1. Se puede explicar las concentraciones de nitrato en pozos individuales por las proporciones relativas de aguas subterráneas modernas y anteriores a 1950. Si las prácticas actuales continúan, se producirá un aumento de las concentraciones de nitrato en la cuenca de Dumfries debido a la disminución de la proporción de aguas antiguas.

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Résumé L'aquifère des grès et brèches du Permien de Dumfries joue un rôle important dans l'alimentation en eau de la principale ville du sud-ouest de l'Écosse. La région est principalement soumise à de l'élevage pastoral avec quelques industries et des piscicultures. La progression de l'exploitation de cet aquifère a révélé l'existence d'un écoulement souterrain complexe en fractures et des concentrations en nitrate croissantes. Dans le but d'étudier ces deux points plus en détail, l'âge et la qualité de l'eau souterraine dans tout l'aquifère ont été évalués en utilisant des techniques hydrogéochimiques conventionnelles avec les CFC et SF₆ comme marqueurs du temps de séjour. L'aquifère est constitué par des unités dominées par des brèches et des grès: les grès de Locharbriggs à l'est et les brèches de Doweel à l'ouest. L'eau souterraine dans tout l'aquifère a un faciès bicarbonaté calcique et magnésien et est moyennement minéralisée; le pH est proche de la neutralité. Le chimisme observé de l'eau souterraine résulte des apports marins par la pluie modifiés par la dissolution du matériau carbonaté des brèches, des grès et des formations superficielles. Les concentrations en CFC et SF₆ sont interprétées sur la base d'un mélange entre des composantes ancienne (>50 ans) et récente (années 1990). Bien qu'il y ait en général une plus forte proportion d'eau ancienne dans les grès de Locharbriggs que dans la brèche de Doweel, les isotopes stables suggèrent que la composante d'eau ancienne dans les grès interstratifiés des brèches est beaucoup plus ancienne, contenant probablement un élément d'eau fossile. Les concentrations en nitrate dans l'aquifère peuvent être directement reliées au taux de recharge récente. L'eau souterraine moderne contient approximativement 9 mg l^–1 en NO₃-N et l'eau souterraine d'avant 1950 environ 2 mg l^–1 en NO₃-N. Les concentrations en nitrate mesurées dans des forages individuels sont expliquées par des proportions relatives d'eaux souterraines moderne et antérieure à 1950. Si les pratiques actuelles continuent, les concentrations en nitrate mesurées dans le bassin de Dumfries augmenteront alors que la part de l'eau souterraine d'avant 1950 diminuera.

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Integrated hydrochemical method of water quality assessment for irrigation in arid areas: application to the Jilh aquifer, Saudi Arabia

Water samples from 72 wells tapping the Jilh aquifer were collected and analyzed for 10 different water quality parameters. Using these data, a regional irrigation water quality was assessed using three techniques: (i) United States Department of Agriculture method (USDA), (ii) Food and Agriculture Organization (FAO) guidelines for water quality assessment, and (iii) Water-Types approach. The USDA method revealed that the aquifer water salinity, as represented by electrical conductivity, EC_w, ranges from high salinity (C3: EC_w > 0.75–2.25 dS/m) to a very high salinity (C4: EC_w > 2.25 dS/m). The sodium adsorption ratio (SAR) varied from low (S1) to very high (S4) sodicity. Therefore, the water of the Jilh aquifer is dominantly of the C4–S2 class representing 56% of the total wells followed by C4–S1, C4–S3, C3–S1 and C4–S4 classes at 19%, 14%, 8%, and 3% of the wells respectively. The FAO system indicated moderate to severe restriction on the use for irrigation and slight to moderate ion toxicities for Na⁺, Cl⁻, B⁺, NO₃⁻ and HCO₃⁻. It is clear that, both USDA and FAO systems condemn the Jilh groundwater as hazardous for irrigation due to its high salt content, unless certain measures for salinity control are undertaken. The dominant salt constituents in the water are Mg–Cl₂, Na–Cl and Ca–Cl₂ as per the Water-Types method. However, due to the complexity in classifying the aquifer groundwater for irrigation, a simplified approach acknowledging three class groups (I-suitable water, II-conditionally suitable water and III-unsuitable water) adopted from the three methods, is suggested in this paper. The simplified approach combines C–S classes of the USDA method among these three groups according to the lowest ratings. The salinity of the FAO method has been split arbitrarily into slight and moderate subclasses with values of 0.7–2.25 and >2.25 dS/m, respectively; to match with the C3-class of the USDA system. The Water-Types were classified assuming that Ca–Cl₂ is the least hazardous salt, followed by Mg–Cl₂ and Na–Cl. Using this integrated hydrochemical method, the majority of the wells (92%) contain unsuitable water for irrigation (Group III) while the remaining wells (8%) are in Group II with water considered conditionally suitable for irrigation.