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1.
Artesian basins contain the largest mineral water resources of the world. There are several types of mineral therapeutic water: sulfate, chloride, radon-rich, iron-rich waters, etc. Artesian basins occupy very large areas in Russia. However, genesis of water and brines is still not very clear. This is one of the most important hydrogeological problems that is being attempted to solve for many years. Most of the Russian hydrogeologists traditionally consider that these waters are of sedimentary origin. However, higher concentrations of bromine, iodine, iron, radon and other balneologically active components can be of different origin, for example, of infiltration or juvenile water. As an example, two areas will be considered – West-Siberian basin and East-European artesian area.West-Siberian artesian basin has very distinct latitudinal and vertical zonation. Latitudinal zonation is caused by climate changes from north to south. As for the vertical zonation, mineralization and chemical composition change in the vertical cross-section and from the periphery to the center within the same aquifer. The main mineral water resources of West-Siberian artesian basin are concentrated in Mesozoic rocks. Brackish waters and low-saturated brines without specific components are used for medical purposes. The most well-known spa is Karachi, which exploits chloride-hydrocarbonate brackish water. Sodium chloride bromine and iodine-bromine waters are used at other health resorts. It is possible to organize extraction of iodine from brines of Tcherkashinsko-Tobolskoe occurrence in Tumen region.East-European artesian area occupies most of the Russian Platform. The most widespread types of mineral water within the Russian Platform are sodium-chloride and magnesium-sulfate waters and brines. Such well-known spas, like Moscow mineral waters, Krainka, Staraya Russa and many others, belong to this type. Resources of these waters are definitely connected with sedimentogenic processes. The upper hydrodynamic zone contains iron-rich, hydrogen sulfide, and sometimes radon-rich water. Their formation is caused by the interaction between waters of infiltration and sedimentary genesis, or between infiltration waters and host rocks. One of the examples is Polustrovo iron-rich water. There are industrially valuable waters containing bromine and iodine.The resources of therapeutic water of sedimentary basins allow to increase balneological potential of spas in Russia. 相似文献
2.
B.R. Scanlon J.P. Nicot R.C. Reedy D. Kurtzman A. Mukherjee D.K. Nordstrom 《Applied Geochemistry》2009,24(11):2061-2071
High groundwater As concentrations in oxidizing systems are generally associated with As adsorption onto hydrous metal (Al, Fe or Mn) oxides and mobilization with increased pH. The objective of this study was to evaluate the distribution, sources and mobilization mechanisms of As in the Southern High Plains (SHP) aquifer, Texas, relative to those in other semiarid, oxidizing systems. Elevated groundwater As levels are widespread in the southern part of the SHP (SHP-S) aquifer, with 47% of wells exceeding the current EPA maximum contaminant level (MCL) of 10 μg/L (range 0.3–164 μg/L), whereas As levels are much lower in the north (SHP-N: 9% As MCL of 10 μg/L; range 0.2–43 μg/L). The sharp contrast in As levels between the north and south coincides with a change in total dissolved solids (TDS) from 395 mg/L (median north) to 885 mg/L (median south). Arsenic is present as arsenate (As V) in this oxidizing system and is correlated with groundwater TDS (Spearman’s ρ = 0.57). The most likely current source of As is sorbed As onto hydrous metal oxides based on correlations between As and other oxyanion-forming elements (V, ρ = 0.88; Se, ρ = 0.54; B, ρ = 0.51 and Mo, ρ = 0.46). This source is similar to that in other oxidizing systems and constitutes a secondary source; the most likely primary source being volcanic ashes in the SHP aquifer or original source rocks in the Rockies, based on co-occurrence of As and F (ρ = 0.56), oxyanion-forming elements and SiO2 (ρ = 0.41), which are found in volcanic ashes. High groundwater As concentrations in some semiarid oxidizing systems are related to high evaporation. Although correlation of As with TDS in the SHP aquifer may suggest evaporative concentration, unenriched stable isotopes (δ2H: −65 to −27; δ18O: −9.1 to −4.2) in the SHP aquifer do not support evaporation. High TDS in the SHP aquifer is most likely related to upward movement of saline water from the underlying Triassic Dockum aquifer. Mobilization of As in other semiarid oxidizing systems is caused by increased pH; however, pH in the SHP aquifer is near neutral (10–90 percentiles, 7.0–7.6). Although many processes, such as competitive desorption with SiO2, VO4, or PO4, could be responsible for local mobilization of As in the SHP aquifer, the most plausible explanation for the regional As distribution and correlation with TDS is the counterion effect caused by a change from Ca- to Na-rich, water as shown by the high correlation between As and Na/(Ca)0.5 ratios (ρ = 0.57). This change in chemistry is related to mixing with saline water that moves upward from the underlying Dockum aquifer. This counterion effect may mobilize other anions and oxyanion-forming elements that are correlated with As (F, V, Se, B, Mo and SiO2). Competition among the oxyanions for sorption sites may enhance As mobilization. The SHP case study has similar As sources to those of other semiarid, oxidizing systems (original volcanic ash source followed by sorption onto hydrous metal oxides) but contrasts with these systems by showing lack of evaporative concentration and pH mobilization of As but counterion mobilization of As instead in the SHP-S aquifer. 相似文献
3.
《Applied Geochemistry》2005,20(7):1292-1308
The Kouris catchment is located in the south of the Troodos massif in Cyprus. It constitutes one of the biggest catchments of the island with important freshwater resources. Geologically, the catchment includes an ophiolitic complex outcropping in the north which is overlaid by sedimentary rocks in the south. The hydrology is driven by a Mediterranean climate, a mountainous topography, and a complex distribution of the hydrogeological properties resulting from the complex geology.To improve the understanding of groundwater hydrology of the Kouris catchment, 176 groundwater and precipitation samples were collected and their 3H contents were analyzed. The three-dimensional 3H transport in the groundwater was simulated by the PMPATH code. For numerical modelling, a regional input function of 3H in precipitation was constructed from a linear regression between data for Cyprus and for neighboring meteorological stations. The calculated residence times for the groundwaters in the sedimentary aquifer and Pillow Lavas were greater than 48 a and were considerably greater than those of the ophiolitic complex (14–30 a). The calibrated aquifer porosities were in a range of 0.05–0.06. The PMPATH model was applied for delineation of spring catchments that were represented by quite narrow zones of lengths up to 5 km.Another contribution resulting from the 3H analysis was a better understanding of the river–aquifer interactions. In most of the southern part, the lithified sediments received only negligible amounts of water from the rivers, while the alluvial aquifer contained mostly water infiltrated from rivers. The largest springs in the southern part, associated with the alluvial aquifer, also discharged water identical to that in the rivers. 相似文献
4.
Hydrogeochemical study of the thermal and mineralized waters of the Banaz (Hamamboğazi) area,western Anatolia,Turkey 总被引:1,自引:1,他引:0
The Hamamboğazi spa in western Turkey was built around natural hot springs with discharge temperatures in the range of 30–54°C;
the waters have near neutral pH values of 6.50–7.10 and a TDS content between 2,694 and 2,982 mg/l. Thermal water with a temperature
of 47.5–73°C has been produced at 325 l/s from five wells since 1994, causing some springs to go dry. A management plan is
required in the study area to maximize the benefits of this resource, for which currently proposed direct uses include heating
in the district and greenhouses, as well as balneology in new spas in the area. The best use for the water from each spring
or well will depend on its temperature, chemistry and location. The thermal waters are mixed Na–Mg–HCO3–SO4 fluids that contain a significant amount of CO2 gas. The chemical geothermometers applied to the Hamamboğazi thermal waters yield a maximum reservoir temperature of 130°C.
Isotope results (18O, 2H, 3H) indicate that the thermal waters have a meteoric origin: rainwater percolates downward along fractures and faults, is heated
at depth, and then rises to the surface along fractures and faults that act as a hydrothermal conduit. The basement around
the Banaz Hamamboğazi resort is comprised of Paleozoic metamorphic schist and marbles exposed 8 km south and 15 km north of
Banaz. Mesozoic marble, limestone and ophiolitic complex are observed a few km west and in the northern part of Banaz. These
units were cut at a depth of 350–480 m in boreholes drilled in the area. Overlying lacustrine deposits are composed of fine
clastic units that alternate with gypsum, tuff and tuffites of 200–350 m thickness. The marble and limestones form the thermal
water aquifer, while lacustrine deposits form the impermeable cap. 相似文献
5.
A. N. Voronov 《Environmental Geology》2000,39(5):477-481
The Russian Federation has many aquifers and these possess a wide range of chemical compositions. In Russia about 300 mineral
water sources have been developed as spas and health resorts. More than 150 of them produce bottled mineral water. A brief
historical revue is given. The study of mineral waters in Russia began as far back as the reign of Peter the Great (1682–1725).
It has been prolonged by works of many Russian scientists.
The details of the chemical composition of the different types of Russian mineral waters and some geological aquifer peculiarities
are described. The most widely used classification of mineral waters in Russia is presented. The present condition of these
waters and the government standards laid down for their use are described. Examples of different mineral waters are given.
Received: 14 April 1998 / Accepted: 8 December 1998 相似文献
6.
The mineral water deposits in Kiseljak are located in the central Dinarids, Bosnia and Herzegovina, in the southwestern edge of Sarajevo–Zenica basin that was formed in the zone of Busova?a fault. Busova?a fault reaches deep into the Earth’s crust and is characterised by the presence of mineral and thermomineral water enriched with CO2 and CO2 springs (mofetes) in the direction of Ilid?a–Kiseljak–Busova?a. Deposits are constructed of layers of Palaeozoic to Cretaceous age. Primary aquifer of mineral waters is Permian clastites and evaporites and secondary Anisian carbonates. Mineral water and CO2 are of different origin. The water is of atmospheric origin. Due to slow circulation, water descends in the primary aquifer where it becomes enriched with CO2 and minerals. Due to high pressure in the primary aquifer mineral water ascends along Busova?a fault, mounts into the secondary aquifer and rises at spring sources. Water is a mixture of two or more waters of different mineralization. Mixing of water occurs in the zone of secondary aquifer even at greater depths without the influence of contemporary climatic factors. Intensive water mixing is indicated by the high ratio of Ca/Sr, Na/Cl and Ca/SO4 and the mixing diagram. CO2 is thermometamorphic, arising from the catalytic activity of SiO2 on carbonates in the deeper layers of the Earth’s crust, where quartz porphyry broke through Palaeozoic formations. 相似文献
7.
Arsenic (As) and antimony (Sb) concentrations and speciation were determined along flow paths in three groundwater flow systems,
the Carrizo Sand aquifer in southeastern Texas, the Upper Floridan aquifer in south-central Florida, and the Aquia aquifer
of coastal Maryland, and subsequently compared and contrasted. Previously reported hydrogeochemical parameters for all three
aquifer were used to demonstrate how changes in oxidation–reduction conditions and solution chemistry along the flow paths
in each of the aquifers affected the concentrations of As and Sb. Total Sb concentrations (SbT) of groundwaters from the Carrizo Sand aquifer range from 16 to 198 pmol kg−1; in the Upper Floridan aquifer, SbT concentrations range from 8.1 to 1,462 pmol kg−1; and for the Aquia aquifer, SbT concentrations range between 23 and 512 pmol kg−1. In each aquifer, As and Sb (except for the Carrizo Sand aquifer) concentrations are highest in the regions where Fe(III)
reduction predominates and lower where SO4 reduction buffers redox conditions. Groundwater data and sequential analysis of the aquifer sediments indicate that reductive
dissolution of Fe(III) oxides/oxyhydroxides and subsequent release of sorbed As and Sb are the principal mechanism by which
these metalloids are mobilized. Increases in pH along the flow path in the Carrizo Sand and Aquia aquifer also likely promote
desorption of As and Sb from mineral surfaces, whereas pyrite oxidation mobilizes As and Sb within oxic groundwaters from
the recharge zone of the Upper Floridan aquifer. Both metalloids are subsequently removed from solution by readsorption and/or
coprecipitation onto Fe(III) oxides/oxyhydroxides and mixed Fe(II)/Fe(III) oxides, clay minerals, and pyrite. Speciation modeling
using measured and computed Eh values predicts that Sb(III) predominate in Carrizo Sand and Upper Floridan aquifer groundwaters,
occurring as the Sb(OH)30 species in solution. In oxic groundwaters from the recharge zones of these aquifers, the speciation model suggests that Sb(V)
occurs as the negatively charged Sb(OH)6− species, whereas in sufidic groundwaters from both aquifers, the thioantimonite species, HSb2S4
− and Sb2S4
2−, are predicted to be important dissolved forms of Sb. The measured As and Sb speciation in the Aquia aquifer indicates that
As(III) and Sb(III) predominate. Comparison of the speciation model results based on measured Eh values, and those computed
with the Fe(II)/Fe(III), S(-II)/SO4, As(III)/As(V), and Sb(III)/Sb(V) couples, to the analytically determined As and Sb speciation suggests that the Fe(II)/Fe(III),
S(-II)/SO4 couples exert more control on the in situ redox condition of these groundwaters than either metalloid redox couple. 相似文献
8.
四川省日乃金矿位于甘孜—理塘蛇绿混杂岩带的南段,区内中生代构造-岩浆活动强烈,发育上、下两套蛇绿岩,日乃金矿即赋存于上部的瓦能蛇绿岩组中,矿化带主要发育在区域性断裂次级的F6和F7之间的断裂破碎带中,矿化范围具有中-低温热液蚀变,形成3条金矿化带,矿体为脉状,长520~1120 m,宽5.18~6.97 m;矿体倾向NW,倾角40°~75°;矿石品位w(Au)=1.89×10-6~3.77×10-6;矿石的主要含金矿物为黄铁矿和毒砂。根据金矿地质特征和主要控矿因素提出矿床的成因类型为与燕山晚期构造-岩浆活动有关的热液交代充填型金矿床,同时归纳了日乃金矿床的控矿因素。 相似文献
9.
宁夏宁东煤田东北部地下水矿化度较高,且具有分布不均和变化较大的特点。通过分析地下水矿化度的空间分布特征,结合区域地质构造、地下水补给径流条件,借助Piper三线图、Gibbs图、离子比例系数等手段,深入研究高矿化度地下水的形成机制。结果表明,宁东煤田东北部地下水矿化度为0.30~23.56 g/L,平均值为5.84 g/L,淡水、微咸水、咸水、盐水所占比例分别为3.16%、50.00%、33.68%、13.16%。水平方向上,基岩裂隙水矿化度由东向西逐渐降低,在鸳鸯湖矿区南部形成高矿化度异常带。此外,在研究区西部及南北部的零星地区出现矿化度较高区。矿化度整体较高与石膏、盐岩及黄铁矿溶解和地下水长期滞流有关,而矿化度由东向西逐渐降低则受鄂尔多斯台地逆冲推覆构造前缘坳陷影响。鸳鸯湖矿区南部位于鄂尔多斯台地南北冲断体系的过渡带,褶曲较完整,地下水环境相对封闭,形成高矿化度异常带。垂直方向上,从Ⅰ含水层至Ⅴ含水层深部含水层的矿化度比浅部高,主要与深部地下水环境封闭,更新较慢有关。该研究将为相似矿区地下水资源开发与利用提供理论依据。 相似文献
10.
The assessment of groundwater quality in shallow aquifers is of high societal relevance given that large populations depend directly on these water resources. The purpose of this study was to establish links between groundwater quality, groundwater residence times, and regional geology in the St. Lawrence Lowlands fractured bedrock aquifer. The study focuses on a 4500 km2 watershed located in the St. Lawrence Lowlands of the province of Quebec in eastern Canada. A total of 150 wells were sampled for major, minor, and trace ions. Tritium (3H) and its daughter element, 3He, as well as radiocarbon activity (A14C) were measured in a subset of wells to estimate groundwater residence times. Results show that groundwater evolves from a Ca–HCO3 water type in recharge zones (i.e., the Appalachian piedmont) to a Na–HCO3 water type downgradient, toward the St. Lawrence River. Locally, barium (Ba), fluoride (F), iron (Fe), and manganese (Mn) concentrations reach 90, 2, 18, and 5.9 mg/L respectively, all exceeding their respective Canadian drinking water limits of 1, 1.5, 0.3, and 0.05 mg/L. Release of these elements into groundwater is mainly controlled by the groundwater redox state and pH conditions, as well as by the geology and the duration of rock–water interactions. This evolution is accompanied by increasing 3H/3He ages, from 4.78 ± 0.44 years upgradient to more than 60 years downgradient. Discrepancies between calculated 3H/3He and 14C water ages (the latter ranging from 280 ± 56 to 17,050 ± 3410 years) suggest mixing between modern water and paleo-groundwater infiltrated through subglacial recharge when the Laurentide Ice Sheet covered the study area, and during the following deglaciation period. A linear relationship between 3H activity and corrected 14C versus Mg/Ca and Ba support a direct link between water residence time and the chemical evolution of these waters. The Ba, F, Fe, and Mn concentrations in groundwater originate from Paleozoic rocks from both the St. Lawrence Platform and the Appalachian Mountains. These elements have been brought to the surface by rising hydrothermal fluids along regional faults, and trapped in sediment during their deposition and diagenesis due to reactions with highly sulfurous and organic matter-rich water. Large-scale flow of meltwater during subglacial recharge and during the subsequent retreat of the Laurentide Ice Sheet might have contributed to the leaching of these deposits and their enrichment in the present aquifers. This study brings a new and original understanding of the St. Lawrence Lowlands groundwater system within the context of its geological evolution. 相似文献
11.
岩溶水水化学特征在水文地质条件分析中的应用——以娘子关泉群岩溶水系统寿阳区为例 总被引:1,自引:0,他引:1
娘子关泉群岩溶水系统寿阳区从补给区到迳流区、排泄区水化学特征变化具有明显的规律性,岩溶水自北向南随着中奥陶统灰岩含水层埋深由浅变深,富水程度由强变弱,径流条件由积极趋滞缓,矿化度、总硬度和SO42-由低变高。为水文地质条件的分析与建立水源地和矿山防治水提供了地质依据。 相似文献
12.
N. A. Kharitonova G. A. Chelnokov E. A. Vakh A. A. Karabtsov N. N. Zykin 《Russian Journal of Pacific Geology》2010,4(1):78-90
The geochemical study of bed rocks, underground and surface waters, and associated gases in the Fadeevskoe deposit of carbonated
waters (Sikhote Alin, Primorye region) revealed that the chemical composition of these waters is formed in the zone of active
water exchange in the limited area of the discharge zone, where hydro carbonate calcic waters with mineralization of up to
1 g/1 are formed in largely potassic-sodic rocks. Calculations of the saturation indices show that the mineral waters are
characterized by the early stage of Ca saturation, being undersaturated with carbonates and aluminosilicates. The main factors
that influence the water mineralization are the excess carbon dioxide in water and the circulation time. The oxygen and carbon
isotope ratios indicate the atmospheric genesis of the aqueous component (δ2H = —117; δ18O = —15.4%o) and the carbon isotope content in the CO2 implies the mantle nature of the carbon dioxide (δ13C = -9.9%o). 相似文献
13.
Implications of ion exchange processes for the formation of lithological and hydrogeochemical systems under various thermobaric conditions of the subsurface hydrosphere are discussed on the basis of on-location, experimental, and thermodynamic studies. It is shown for the case of the Volga–Ural sedimentary basin that ion exchange interaction in the water–rock system bears a zonal character and is differentiated with depth. Exchange and adsorption processes are most efficient in the upper 500-m-thick supergene zone composed of terrigenous clayey rocks, where the HCO3–Na- and SO4–Na-waters with a mineralization reaching 20 g/dm3 are formed. In cata- and metagenetic zones at a depth of more than 1000–1500 m, these processes do not strongly affect the brine composition. Metasomatic dolomitization of limestones as an exchange adsorption process plays the crucial role in the formation of Cl–Ca-brines at that depth. 相似文献
14.
Spatio-temporal characterization of the Pliocene aquifer conditions in Wadi El-Natrun area,Egypt 总被引:3,自引:1,他引:2
Wadi El-Natrun area has recently undergone extensive urban and agricultural expansion. Due to the absence of natural surface
irrigation supplies, the only source of water in the area is the Pliocene groundwater aquifer. As a result, secondary salinization
from increased abstractions is the major threat to the groundwater aquifer. There is a dire need for efficient strategies
to ensure long-term sustainability of the area’s productive agriculture. These strategies should be based on scientific spatio-temporal
monitoring and analysis of the groundwater conditions that is also lacking. To capture the spatio-temporal variability in
groundwater conditions, field measurements of total dissolved solids, electrical conductivity, pH, temperature, and water
level as well as lab-based ionic composition were performed on 47 groundwater samples collected during 2006 and 2007. Determinations
of the hydrochemical characteristics, water types, salt assemblages, and the sodium adsorption ratio were carried out on the
samples. Reference data sets recorded in 1973 and 1997 were available for the area and were used to monitor the changes occurred
in these periods. Geographic information system (GIS) was appraised for mapping and for integrated analysis of the different
layers. Remotely sensed change detection techniques were applied to the Landsat TM and the ETM + imageries and used to highlight
the extensive reclamation and urbanization and to find key trends for the alterations in the groundwater conditions and their
spatial association with land covers. Results revealed a topographic depression-induced flow pattern, predominance of leaching
and dissolution processes, the presence of saline lakes, over-pumping from the Pliocene aquifer, and temporal changes in land
uses are the main factors combined to control the spatio-temporal variability in the groundwater. Results also clarified the
presence of two: northwestern and southeastern zones that varied distinctively in their hydrodynamic and hydrochemical characteristics.
The northwestern zone showed an average water level decline of 15 m, the water of which is brackish (av. 2,037 mg/l) with dominant Na+, Cl− and SO4
2− ions. The groundwater of this zone is characterized by high to very high salinity hazard and high to very high alkali hazard
and is not recommended for irrigation on soils with poor drainage and without proper management for salinity control. The
southeastern zone showed water level decline less than 2 m, the water of which is fresh (av. 424 mg/l) with major Na+, HCO3
−, Cl−, and SO4
2− ions, and quality suitable for irrigation with medium to high salinity and low to medium alkali hazards. The article represents
the first step towards an integrated management of Wadi El-Natrun groundwater resources within a GIS framework. 相似文献
15.
《Applied Geochemistry》2006,21(7):1204-1215
Understanding the fate of injected organic matter and the consequences of subsequent redox processes is essential to assess the viability of using reclaimed water in aquifer storage and recovery (ASR). A full-scale field trial was undertaken at Bolivar, South Australia where two ASR cycles injected approximately 3.6 × 105 m3 of reclaimed water into a carbonate aquifer over a 3-a period. Organic C within reclaimed water was predominantly in the dissolved fraction, ranging from 1 to 2 mmol L−1 (10–20 mg L−1), markedly higher than potable supply and stormwater previously reported as source waters for ASR. Between 20% and 24% of the injected dissolved organic C (DOC) was mineralised through reaction with injected O2 and NO3. Furthermore, this was achieved mainly within the first 4 m of aquifer passage. Despite the presence of residual DOC, SO4 reduction was not induced within the bulk of the injected plume. It was only near the ASR well during an extended storage phase where deeply reduced (methanogenic) conditions developed, indicating variable redox zones within the injectant plume. The quality of water recovered from the ASR well indicated that the organic C content of reclaimed water does not restrict its application as a recharge source for ASR. 相似文献
16.
There are many factors affecting ungerground water chemistry of an oil-bearing sedimentary basin.The properties of underground water show variations in the vertical direction, giving rise to a vertical zonation with respect to underground water chemistry,Five zones could be divided downwards,including 1)The freshening zone due to meteoric water leaching (A):2)the evaporation-concentration zone near the surface(B);3) the freshening zone due to stratum compaction-released water(C1)-infiltration-concentration zone during the mudstone compaction and water releasing(C2);4) the freshening zone for clay mineral dehydration(D);and 5)the seepage-concentration zone(E).The hydrodynamic fields in the Songliao Basin are obviously asymmetrical,with the characteristics of gravity-induced centripetal flow recharged by meteoric water along the edge to the inner part of the basin mainly in its northern and eastern regions,centrifugal flow and crossformational flow in the center of the basin,as well as the cross-formation flow-evaporation discharge area in its southern area.Hydrodynamics controls the planar distribution of underground-water chemical fields;1)the freshening area due to penetrating meteoric water generally at the basin edges;2)the freshening area for mudstone compaction-released water at the center of the basin;3) the cross-formational area as the transitional aqrea;and 4)the concentration area by cross-formational flow and evaporation.The mineralization degree and the concentrations of Na^ and Cl^- and their salinity coefficeents tend to increase,while the concentrations of(CO3^2- HCO3^-) and SO4^2- and the metamorphism and desulfuration coefficients tend to decrease along the centrifugal flow direction caused by mudstone compaction in the depression area.But all of them tend to increase along the gravity-induced centripetal flow direction. 相似文献
17.
《Applied Geochemistry》2000,15(9):1383-1397
Water pollution arising from base metal sulphide mines is problematic in many countries, yet the hydrogeology of the subsurface contaminant sources is rarely well-characterized. Drainage water pumped from an active F–Pb mine in northern England has unusual chemistry (alkaline with up to 40 mg.l−1 Zn) which profoundly impacts the ecology of the receiving watercourse. Detailed in-mine surveys of the quantity and quality of all ground water inflows to the mine were made. These revealed major, temporally persistent heterogeneities in ground water quality, with three broad types of water identified as being associated with distinct hydrostratigraphic units. Type I waters (associated with the Firestone Sill aquifer) are cool (<10°C), Ca–HCO3–SO4 waters, moderately mineralized (specific electrical conductance (SEC)≤410 μS.cm−1) with <4 mg.l−1 Zn. Type II waters (associated with the Great Limestone aquifer) are warmer (≈15°C), of Ca–SO4 facies, highly mineralized (SEC≤1500 μS.cm−1) with ≤40 mg.l−1 Zn. Type III waters (in the deepest workings) are tepid (>18°C), of Ca–HCO3–SO4 facies, intermediately mineralized (SEC≤900 μS.cm−1) with ≤13 mg.l−1 Zn, and with significant Fe (≤12 mg.l−1) and Pb (≤8 mg/l). Monotonic increases in temperature and Cl− concentration with depth contrast with peaks in total mineralization, SO4 and Zn at medium depth (in Type II waters). Sulphate, Pb and Zn are apparently sourced via oxidation of galena and sphalerite, which would release each metal in stoichiometric equality with SO4. However, molal SO4 concentrations typically exceed those of Pb and Zn by 2–3 orders of magnitude, which mineral equilibria suggest is due to precipitation of carbonate “sinks” for these metals. Contaminant loading budgets demonstrate that, although Type II waters amount to only 25% of the total ground water inflow to the mine, they account for almost 60% of the total Zn loading. This observation has important management implications for both the operational and post-abandonment phases of the mine life cycle. 相似文献
18.
The northern section of the Bohemian Cretaceous Basin has been the site of intensive U exploitation with harmful impacts on groundwater quality. The understanding of groundwater flow and age distribution is crucial for the prediction of the future dispersion and impact of the contamination. State of the art tracer methods (3H, 3He, 4He, 85Kr, 39Ar and 14C) were, therefore, used to obtain insights to ageing and mixing processes of groundwater along a north–south flow line in the centre of the two most important aquifers of Cenomanian and middle Turonian age. Dating of groundwater is particularly complex in this area as: (i) groundwater in the Cenomanian aquifer is locally affected by fluxes of geogenic and biogenic gases (e.g. CO2, CH4, He) and by fossil brines in basement rocks rich in Cl and SO4; (ii) a thick unsaturated zone overlays the Turonian aquifer; (iii) a periglacial climate and permafrost conditions prevailed during the Last Glacial Maximum (LGM), and iv) the wells are mostly screened over large depth intervals.Large disagreements in 85Kr and 3H/3He ages indicate that processes other than ageing have affected the tracer data in the Turonian aquifer. Mixing with older waters (>50 a) was confirmed by 39Ar activities. An inverse modelling approach, which included time lags for tracer transport throughout the unsaturated zone and degassing of 3He, was used to estimate the age of groundwater. Best fits between model and field results were obtained for mean residence times varying from modern up to a few hundred years. The presence of modern water in this aquifer is correlated with the occurrence of elevated pollution (e.g. nitrates).An increase of reactive geochemical indicators (e.g. Na) and radiogenic 4He, and a decrease in 14C along the flow direction confirmed groundwater ageing in the deeper confined Cenomanian aquifer. Radiocarbon ages varied from a few hundred years to more than 20 ka. Initial 14C activity for radiocarbon dating was calibrated by means of 39Ar measurements. The 14C age of a sample recharged during the LGM was further confirmed by depleted stable isotope signatures and near freezing point noble gas temperature. Radiogenic 4He accumulated in groundwater with concentrations increasing linearly with 14C ages. This enabled the use of 4He to validate the dating range of 14C and extend it to other parts of this aquifer. In the proximity of faults, 39Ar in excess of modern concentrations and 14C dead CO2 sources, elevated 3He/4He ratios and volcanic activity in Oligocene to Quaternary demonstrate the influence of gas of deeper origin and impeded the application of 4He, 39Ar and 14C for groundwater dating. 相似文献
19.
D. I. Cendón S. I. Hankin J. P. Williams M. Van der Ley M. Peterson C. E. Hughes 《Australian Journal of Earth Sciences》2014,61(3):475-499
Groundwater residence time in the Kulnura–Mangrove Mountain aquifer was assessed during a multi-year sampling programme using general hydrogeochemistry and isotopic tracers (H2O stable isotopes, δ13CDIC, 3H, 14C and 87Sr/86Sr). The study included whole-rock analysis from samples recovered during well construction at four sites to better characterise water–rock interactions. Based on hydrogeochemistry, isotopic tracers and mineral phase distribution from whole-rock XRD analysis, two main groundwater zones were differentiated (shallow and deep). The shallow zone contains oxidising Na–Cl-type waters, low pH, low SC and containing 3H and 14C activities consistent with modern groundwater and bomb pulse signatures (up to 116.9 pMC). In this shallow zone, the original Hawkesbury Sandstone has been deeply weathered, enhancing its storage capacity down to ~50 m below ground surface in most areas and ~90 m in the Peats Ridge area. The deeper groundwater zone was also relatively oxidised with a tendency towards Ca–HCO3-type waters, although with higher pH and SC, and no 3H and low 14C activities consistent with corrected residence times ranging from 11.8 to 0.9 ka BP. The original sandstone was found to be less weathered with depth, favouring the dissolution of dispersed carbonates and the transition from a semi-porous groundwater media flow in the shallow zone to fracture flow at depth, with both chemical and physical processes impacting on groundwater mean residence times.Detailed temporal and spatial sampling of groundwater revealed important inter-annual variations driven by groundwater extraction showing a progressive influx of modern groundwater found at >100 m in the Peats Ridge area. The progressive modernisation has exposed deeper parts of the aquifer to increased NO3? concentrations and evaporated irrigation waters. The change in chemistry of the groundwater, particularly the lowering of groundwater pH, has accelerated the dissolution of mineral phases that would generally be inactive within this sandstone aquifer triggering the mobilisation of elements such as aluminium in the aqueous phase. 相似文献
20.
Vein-type gold deposits in the Atud area are related to the metagabbro–diorite complex that occurred in Gabal Atud in the Central Eastern Desert of Egypt. This gold mineralization is located within quartz veins and intense hydrothermal alteration haloes along the NW–SE brittle–ductile shear zone, as well as along the contacts between them. By using the mass balance calculations, this work is to determine the mass/volume gains and losses of the chemical components during the hydrothermal alteration processes in the studied deposits. In addition, we report new data on the mineral chemistry of the alteration minerals to define the condition of the gold deposition and the mineralizing fluid based on the convenient geothermometers. Two generations of quartz veins include the mineralized grayish-to-white old vein (trending NW–SE), and the younger, non-mineralized milky white vein (trending NE–SW). The ore minerals associated with gold are essentially arsenopyrite and pyrite, with chalcopyrite, sphalerite, enargite, and goethite forming during three phases of mineralization; first, second (main ore), and third (supergene) phases. Three main hydrothermal alteration zones of mineral assemblages were identified (zones 1–3), placed around mineralized and non-mineralized quartz veins in the underground levels. The concentrations of Au, Ag, and Cu are different from zone to zone having 25–790 ppb, 0.7–69.6 ppm, and 6–93.8 ppm; 48.6–176.1 ppb, 0.9–12.3 ppm, and 39.6–118.2 ppm; and 53.9–155.4 ppb, 0.7–3.4 ppm, and 0.2–79 ppm for zones 1, 2, and 3, respectively.The mass balance calculations and isocon diagrams (calculated using the GEOISO-Windows program) revealed the gold to be highly associated with the main mineralized zone as well as sericitization/kaolinitization and muscovitization in zone 1 more than in zones 2 and 3. The sericite had a higher muscovite component in all analyzed flakes (average XMs = 0.89), with 0.10%–0.55% phengite content in wall rocks and 0.13%–0.29% phengite content in mineralized quartz veins. Wall rocks had higher calcite (CaCO3) contents and lower MgCO3 and FeCO3 contents than the quartz veins. The chlorite flakes in the altered wall rocks were composed of pycnochlorite and ripidolite, with estimated formation temperatures of 289–295 °C and 301–312 °C, respectively. Albite has higher albite content (95.08%–99.20%) which occurs with chlorite in zone 3. 相似文献