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1.
多矩形图解法及其在塔里木盆地中的应用 总被引:1,自引:0,他引:1
周金龙 《水文地质工程地质》2006,33(2):4-6
多矩形图解法(MRD)采用9个相邻的多矩形坐标系,分别代表9种地下水类型,它具有容纳大量地下水化学分析数据的功能。图解结果不但可以清楚地显示地下水中阴、阳离子含量的信息,而且也提供了更明晰、易懂的水化学类型的信息。本文简要地叙述了MRD法的原理,并应用该方法分析了塔里木盆地各流域地下水的水化学类型,结果表明:MRD法可以清晰地表征塔里木盆地地下水水化学类型的空间变化特征。 相似文献
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A preliminary analysis of the formation of travertine and travertine cones in the Jifei hot spring,Yunnan, China 总被引:3,自引:2,他引:1
Yaping Liu Xun Zhou Bin Fang Haiyan Zhou Tsutomu Yamanaka 《Environmental Earth Sciences》2012,66(7):1887-1896
The Jifei hot spring emerges in the form of a spring group in the Tibet–Yunnan geothermal zone, southwest of Yunnan Province, China. The temperatures of spring waters range from 35 to 81°C and are mainly of HCO3–Na·Ca type. The total discharge of the hot spring is about 10 L/s. The spring is characterized by its huge travertine terrace with an area of about 4,000 m2 and as many as 18 travertine cones of different sizes. The tallest travertine cone is as high as 7.1 m. The travertine formation and evolution can be divided into three periods: travertine terrace deposition period, travertine cone formation period and death period. The hydrochemical characteristics of the Jifei hot spring was analyzed and compared with a local non-travertine hot spring and six other famous travertine springs. The results indicate that the necessary hydrochemical conditions of travertine and travertine cones deposition in the Jifei area are (1) high concentration of HCO3 − and CO2; (2) about 52.9% deep source CO2 with significantly high value; (3) very high milliequivalent percentage of HCO3 − (97.4%) with not very high milliequivalent percentage of Ca2+ (24.4%); and (4) a large saturation index of calcite and aragonite of the hot water. 相似文献
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Earthquake-related hydrochemical changes in thermal springs have been widely observed; however, quantitative modeling of the reactive transport process is absent. In the present study, we apply reactive transport simulation to capture the hydrochemical responses in a thermal spring following the Wenchuan Ms 8.0 and Lushan Ms 7.0 earthquakes. We first constrain deep reservoir geothermal fluid compositions and temperature by multicomponent geothermometry, and then a reactive geochemical transport model is constructed to reproduce the hydrochemical evolution process. The results show that the recharge from the shallow aquifer increases gradually until it reaches a peak because of the permeability enhancement caused by the Lushan earthquake, which may be the mechanism to explain the earthquake-related hydrochemical responses. In contrast to the postseismic effect of the Wenchuan earthquake, the chemical evolution can be considered as hydrochemical anomalies related to the Lushan earthquake. This study proves that the efficient simulation of reactive transport processes is useful for investigating earthquake-related signals in hydrochemical time series. 相似文献
4.
针对地下水资源过量开采而出现的绿洲水文生态问题,以贺兰山西麓具有典型特征的内蒙古腰坝绿洲为研究对象,分开采期、非开采期对地下水进行系统取样分析,综合运用描述性统计、相关性分析、离子比例系数和Piper三线图示法,全面系统地研究了地下水水化学的时空变异特征与演变规律。研究结果表明:①季节变化对潜水和承压水水化学类型空间变异性影响较小,潜水水文化学性质受外界因素干扰较大,承压水受外界因素干扰较少;②蒸发浓缩、阳离子交换和人为混合是控制研究区潜水水质演变的主要水文化学过程;③潜水子系统总溶解固体较高,水化学类型变化也较复杂,主要从HCO3·SO4.Cl-Na·Mg·Ca型向Cl·SO4·HCO3-Mg·Na、Cl·SO4-Na·Mg型演化。承压水水化学类型比较单一,主要以低矿化度的HCO3-Na·Mg·Ca型为主。 相似文献
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在放射性废物处置库的选址过程中,地下水水化学特征是最重要的因素之一。为了查明西北某放射性废物处置预选区地下水水化学特征及其演化机制,对该区地下水水样进行了水质测试,综合运用Piper三线图法、相关性分析、饱和指数模拟和质量平衡反应模拟,全面分析了该预选区地下水水化学类型的空间分布和地下水水演化的主要水文化学过程。结果表明:研究区地下水在北部山区接受补给,并向南运移,地下水类型随径流由SO4.Cl—Na型转变为Cl.SO4—Na型。地下水在径流过程中主要经历了溶滤作用、蒸发浓缩作用和阳离子交换作用等水文化学过程,它们是控制该区地下水水化学组分演化的关键。 相似文献
7.
Jobin Thomas Sabu Joseph K. P. Thrivikramji T. M. Manjusree K. S. Arunkumar 《Environmental Earth Sciences》2014,71(5):2333-2351
A comprehensive and systematic study to understand various geochemical processes as well as process drivers controlling the water quality and patterns of the hydrochemical composition of river water in Muthirapuzha River Basin, MRB (a major tributary of Periyar, the longest river in Kerala, India), was carried out during various seasons, such as monsoon, post-monsoon and pre-monsoon of 2007–2008, based on the data collected at 15 monitoring stations (i.e., 15 × 3 = 45 samples). Ca2+ and Mg2+ dominate the cations, while Cl? followed by HCO3 ? dominates the anions. In general, major ion chemistry of MRB is jointly controlled by weathering of silicate and carbonate rocks, which is confirmed by relatively larger Ca2+ + Mg2+/Na+ + K+ ratios as well as Ca2+/Na+ vs. Mg2+/Na+ and Ca2+/Na+ vs. HCO3 ?/Na+ scatter plots. The relationship between Cl? and Na+ implies stronger contributions of anthropogenic activities modifying the hydrochemical composition, irrespective of seasons. The water types emerged from this study are transitional waters or waters that changed their chemical character by mixing with waters of geochemically different ionic signatures. However, various ionic ratios, hydrochemical plots and graphical diagrams suggest seasonality over the hydrochemical composition, which is solely controlled by the rainfall pattern. Relatively higher pCO2 indicates the disequilibrium existing in natural waterbodies vis-à-vis the atmosphere, which is an outcome of both the contribution of groundwater to stream discharge and anthropogenic activities. Hence, continuous monitoring of hydrochemical composition of mountain rivers is essential in the context of climate change, which has serious implications on tropical mountain fluvial-hydro systems. 相似文献
8.
艾比湖区域地表水水化学特征干湿季变化及其控制因素 总被引:1,自引:0,他引:1
对2014年艾比湖区域的地表水进行观测和取样,综合运用多元统计、Piper阴阳离子三角图、Gibbs图等方法,对艾比湖区域干湿季地表水化学特征及控制因素进行了分析.结果表明:在湿季5月,Na+和Cl-是占绝对优势的离子,分别占阳离子和阴离子总量的70.34%和52.97%,其次是Mg2+和SO42-;在干季10月,Na+和Cl-是占绝对优势的离子,分别占阳离子和阴离子总量的70.57%和66.48%,其次是Mg2+和SO42-.进而判断出在湿季,艾比湖区域地表水水化学类型为以碳酸盐岩石和蒸发岩来源为主的HCO3--Ca2+-Na+型;而在干季,艾比湖区域地表水水化学类型为以碳酸盐岩石和蒸发岩来源为主的HCO3--Ca2+型.此外,探讨了离子控制的因素.就自然因素而言,在干湿季,艾比湖区域地表水化学离子组成受岩石风化作用和蒸发结晶作用的共同影响,大气降水的输入作用十分微弱.就人为因素而言,根据相关研究,干湿季人为活动中的主要因素是人口和地区生产总值,说明该区域受到人为活动的影响.本研究为我国干旱地区对于河水水化学变化、水质特征、水质保护都具有重要的意义. 相似文献
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为探索地下水硝酸盐背景值获取方法,文章以柳江盆地为研究对象,在对比分析国内外研究方法的基础上,首先采用绝对含量和毫克当量百分位数双因子法从宏观上剔除硝酸盐异常数据,然后再利用层次聚类分析结合主成分分析法,分析地下水水化学特征及识别异常分类,进一步剔除异常数据。最后剩余数据进行分布类型检验,采用浓度累计频率法确定地下水硝酸盐背景值范围。研究结果表明,绝对含量和毫克当量百分位数双因子法虽然不能完全剔除异常值,但可为后续层次聚类分析异常识别减少异常信息和子集;层次聚类分析法注重对各亚类的水化学特征分析来识别分析异常数据,具有识别人为异常和天然异常的优势。对比分析常用的数理学方法计算表明,2种方法结合,更能有效识别异常,计算出的地下水硝酸盐背景值更合理。异常数据剔除分析表明,柳江盆地浅层地下水硝酸盐异常与农业化肥的超量施用和居民生活污水与垃圾粪便的下渗污染具有密切的关系。 相似文献
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石英的微量元素记录了石英生长的物理化学条件。通过微量元素对石英原岩进行分类的研究历史已久,经典工作是在以微量元素为坐标轴的图解上绘制各类型石英的分布范围,以区分石英类型。经典图解包括Rusk(2012)提出用于区分三种矿床类型石英的Al-Ti二元图解,和Schr9n et al.(1988)提出的用于判别不同岩浆岩类型石英的Ti-Al-Ge三元图解。越来越多的研究表明,上述图解不能满足对更多石英类型进行分类的需求,同时也出现与部分已知产状类型的石英微量元素判别相矛盾的情况。随着石英原位微区测试方法的成熟,高精度石英微量元素数据逐渐丰富为系统开展机器学习提供了大数据基础,为石英微量元素研究提供了新的角度和可能性。本研究运用机器学习分类方法对石英微量元素进行精确数学分析,提出Ti/Ge-P图解为石英成因研究提出新的地球化学指标。本文同时测试了六种经典机器学习分类算法,提高Ti/Ge-P图解在石英成因分类研究上的精度。此Ti/Ge-P图解适用于多种矿床研究,包括但不局限于斑岩型矿床、矽卡岩型矿床、浅成低温热液型矿床、卡林型矿床以及造山型矿床中的石英。这项工作是大数据技术与机器学习技术在地球化学研究中的积极探索。 相似文献
11.
肥城市岩溶水水化学特征及形成机制 总被引:2,自引:1,他引:1
系统分析地下水长期实测数据,并综合运用数理统计方法、水文地质学、水文地球化学的基本理论,探讨了肥城市水化学特征及其时空分布规律、水化学特征形成机制及水文地球化学过程。结果表明:肥城市地下水水化学类型主要为HCO3·SO4—Ca·Mg型,部分为HCO3·SO4·Cl—Ca·Mg型和HCO3·Cl—Ca·Mg型,主要阴离子由HCO3-向SO42-和Cl-偏移,总溶解固体(TDS)及总硬度呈明显增大趋势;地下水多数离子浓度从补给区经径流区到排泄区越来越高;方解石和石膏的溶滤作用是研究区内地下水水化学成分变化的主要影响因素,同时存在部分的盐岩溶解及阳离子交替吸附作用,而人类活动也是不可忽视的重要影响因素。 相似文献
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衡水地区多年超采深层地下水,形成了以衡水市区为中心的区域地下水降落漏斗,改变了初始的水动力场和水化学场。运用聚类分析、Piper三线图、Gibbs图、氯碱指数、离子相关关系方法分析了该地区历史时期和现阶段深层地下水的水文地球化学特征及其演化规律,探讨了水化学组分的来源及形成机制。结果表明:该地区深层地下水水化学演化受到了较大的人类活动影响,根据Q型聚类分析将研究区划分为补给、径流、排泄3个水化学分区。20世纪70年代到现阶段,随降落漏斗产生发展,研究区形成了新的局部补径排关系,加强了地下水对围岩的溶滤作用,导致研究区水化学场发生了变化,径流区地下水水化学类型由Cl·HCO3-Na、HCO3·Cl-Na和SO4·Cl-Na转化为SO4·Cl-Na和Cl·SO4-Na,排泄区地下水水化学类型由Cl·HCO3-Na和Cl-Na转化为Cl-Na。Gibbs图和离子关系显示,研究区现阶段深层地下水在降落漏斗影响下,水化学组分主要受岩石风化、阳离子交替吸附和脱碳酸作用控制。 相似文献
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搭格架温泉水化学特征及其约束因素研究 总被引:1,自引:0,他引:1
搭格架地热区温泉水DJ1-DJ116号样品于2009年采集,阳离子及微量元素含量采用ICP-OES法测试,Cl-含量采用滴定法测试,其余阴离子含量采用紫外-可见光分光光度法测试。通过对温泉水化学指标的分析,研究温泉的水化学特征及约束因素。其温泉水化学类型为HCO3-Na型,平均矿化度为1 524 mg/L,具有较高的Na/Cl值,温泉水演化程度较高,为完全平衡水,热储中的水岩反应达到了平衡状态.温泉水中PO2极低,PCO2较高;大部分温泉水中玉髓、石英和无定形态SiO2三种硅质热液矿物的饱和度指数大于0。K-Na温标计算热储平均平衡温度为251.36℃;泉水中的Na+、K+离子活度主要受到钠、钾长石的约束。微量元素组合表现出花岗岩源的特征。总体上搭格架地热区温泉水化学特征受到区域地质背景的约束。 相似文献
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James A. Davis 《Geochimica et cosmochimica acta》1982,46(11):2381-2393
Natural organic matter is readily adsorbed by alumina and kaolinite in the pH range of natural waters. Adsorption occurs by complex formation between surface hydroxyls and the acidic functional groups of the organic matter. Oxides with relatively acidic surface hydroxyls, e.g. silica, do not react strongly with the organic matter. Under conditions typical for natural waters, almost complete surface coverage by adsorbed organic matter may be expected for alumina, hydrous iron oxides and the edge sites of aluminosilicates. Potentiometric titration and electrophoresis indicate that most of the acidic functional groups of the adsorbed organic matter are neutralized by protons from solution. The organic coating is expected to have a great influence on subsequent adsorption of inorganic cations and anions. 相似文献
16.
A study on the mixing proportion in groundwater samples by using Piper diagram and Phreeqc model 总被引:1,自引:0,他引:1
Karmegam U. Chidambaram S. Prasanna M.V. Sasidhar P. Manikandan S. Johnsonbabu G. Dheivanayaki V. Paramaguru P. Manivannan R. Srinivasamoorthy K. Anandhan P 《中国地球化学学报》2011,30(4):490-495
Piper (1944) diagram has been the basis for several important interpretations of the hydrogeochemical data. As seen in this diagram, most natural waters contain relatively few dissolved constituents, with cations (metals or bases) and anions (acid radicles) in chemical equilibrium with one another. Apart from the facies representation, the composition of the mixed sample can be identified in terms of the composition of the parental solution. To bring out this advantage of the Piper diagram, a study was conducted in the Kalpakkam region of Tamilnadu, South India. By taking the geology and water table into consideration, two sample locations were selected as parent solution and third one as the mixture sample. All three samples were analyzed for calcium (Ca), magnesium (Mg), sodium (Na), potassium (K), chloride (Cl), sulphate (SO4) and phosphate (PO4) by Ion Chromatograph (Metrohm IC 861). HCO3 was determined by volumetric titration. The Piper diagram shows that parent solutions clustered towards Na-Mg-Ca-HCO3-Cl and Na-HCO3 facies, and the mixing sample belongs to Na-Mg-HCO3 facies. Phreeqc interac-tive (Ver 2.8) along with the original composition of the mixture sample was used to correlate the mixing proportion identified by the Piper diagram. 相似文献
17.
贵州省饮用天然矿泉水资源非常丰富,且水质优良,本文对贵州省岩溶地区饮用天然矿泉水进行了系统的水样采集、水质化验等工作。检测结果显示,贵州省岩溶区饮用天然矿泉水pH值7. 0~8. 1,为中性水;溶解性总固体(TDS)含量介于160. 64~925. 10 mg/L之间,平均含量为369. 70 mg/L,属淡水;总硬度(以CaCO_3计) 136. 8~740. 6 mg/L,平均硬度为293. 0 mg/L,属微硬-硬水;有益元素锶含量介于0. 11~6. 91 mg/L之间,平均含量为1. 28 mg/L,总体上,贵州省饮用天然矿泉水属中性微硬-硬富锶型淡水。Piper三线图显示其水化学类型以HCO~(3-)-Ca~(2+)(Mg~(2+))为主。基于前人研究成果,并结合多种地球化学图解分析,旨在剖析贵州省饮用天然矿泉水水化学特征,探讨其宏量组分来源。贵州省饮用天然矿泉水Gibbs图解显示,其水化学组分主要来源于岩石风化淋滤作用,部分受大气降雨影响较明显; Mg/Na-Ca/Na图解投点均落于碳酸盐岩和硅酸盐岩之间,且明显偏向于碳酸盐岩,指示其主要受控于碳酸盐岩的溶滤作用;HCO~(3-)-(Mg~(2+)/Ca~(2+))图解投点主要集中在方解石和白云石过渡区域,显示其主要来源于方解石的溶解,白云石溶解亦有一定贡献。通过宏量组分来源相关分析,对贵州省岩溶地区饮用天然矿泉水成因规律的认识有一定指导意义。 相似文献
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基于主成分分析的岩溶水水化学组成及影响因素研究——以贵州水城盆地为例 总被引:3,自引:0,他引:3
2015年9月对贵州水城盆地进行采样,共采集地下水样品12个,地表水样品10个,综合运用相关性分析、主成分分析等方法,并结合PHREEQC软件对矿物饱和度指数的计算结果,探讨了地下水、地表水水化学特征现状及其影响因素。研究结果表明:水城盆地岩溶水的水化学类型主要为HCO3-Ca型,部分为SO4-Ca型,地下水和地表水水化学组成主要受Ca2+、K++Na+、HCO3-、SO42-和Cl-影响。研究区地下水和地表水中Ca2+和HCO3-主要来源于碳酸盐岩地区的水-岩反应,水体中Cl-、NO3-和Na+主要来源于城镇生活污水、屠宰废水排放。地下水水质受水-岩反应影响,部分区域受到人类活动干扰明显;地表水水质在钟山区方向主要受沿途生活污水和农业面源污水汇入影响显著,而在水城县方向受煤矿企业排放废水影响较大。 相似文献
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通过在江油市规划应急水源地及其上、下游采集地下水水样进行化学分析,共采集15个样品。结合主离子浓度、Piper图及沿程变化对该水源地地下水的水化学特征及其上、下游地下水水化学变化规律进行分析,结果表明:研究区地下水呈弱碱性,属硬度水和极硬度水,TDS平均值为281.446 mg/L,其中阳离子以Ca2+、Mg2+为主,Na++K+次之;阴离子以HCO3-和SO42-为主,Cl-较少;地下水的化学类型为HCO3--Ca2+。在沿程变化上,自上游至下游,地下水TDS及主离子均有整体增加的现象。地下水化学类型由HCO3--Ca2+型变化为HCO3-·SO42--Ca2+·Mg2+型。 相似文献
20.
Suitability assessment of deep groundwater for drinking and irrigation use in the Djeffara aquifers (Northern Gabes,south-eastern Tunisia) 总被引:1,自引:0,他引:1
Mohsen Ben Alaya Salwa Saidi Thouraya Zemni Fouad Zargouni 《Environmental Earth Sciences》2014,71(8):3387-3421
The multilayered Djeffara aquifer system, south-eastern Tunisia, has been intensively used as a primary source to meet the growing needs of the various sectors (drinking, agricultural and industrial purposes). The analysis of groundwater chemical characteristics provides much important information useful in water resources management. Detailed knowledge of the geochemical evolution of groundwater and assessing the water quality status for special use are the main objective of any water monitoring study. An attempt has been made for the first time in this region to characterize aquifer behavior and appreciate the quality and/or the suitability of groundwater for drinking and irrigation purposes. In order to attend this objective, a total of 54 groundwater samples were collected and analyzed during January 2008 for the major cations (sodium, calcium, magnesium and potassium), anions (chloride, sulfate, bicarbonate), trace elements (boron, strontium and fluoride), and physicochemical parameters (temperature, pH, total dissolved salts and electrical conductivity). The evolution of chemical composition of groundwater from recharge areas to discharge areas is characterized by increasing sodium, chloride and sulfate contents as a result of leaching of evaporite rock. In this study, three distinct chemical trends in groundwater were identified. The major reactions responsible for the chemical evolution of groundwater in the investigated area fall into three categories: (1) calcite precipitation, (2) gypsum and halite dissolution, and (3) ion exchange. Based on the physicochemical analyses, irrigation quality parameters such as sodium absorption ratio (SAR), percentage of sodium, residual sodium carbonate, residual sodium bicarbonate, and permeability index (PI) were calculated. In addition, groundwater quality maps were elabortaed using the geographic information system to delineate spatial variation in physico-chemical characteristics of the groundwater samples. The integration of various dataset indicates that the groundwater of the Djeffara aquifers of the northern Gabes is generally very hard, brackish and high to very high saline and alkaline in nature. The water suitability for drinking and irrigation purposes was evaluated by comparing the values of different water quality parameters with World Health Organization (WHO) guideline values for drinking water. Piper trilinear diagram was constructed to identify groundwater groups where the relative major anionic and cationic concentrations are expressed in percentage of the milliequivalent per liter (meq/l), and it was demonstrated that the majority of the samples belongs to SO4–Cl–Ca–Na, Cl–SO4–Na–Ca and Na–Cl hydrochemical facies. As a whole, all the analyzed waters from this groundwater have revealed that this water is unsuitable for drinking purposes when comparing to the drinking water standards. Salinity, high electric conductivity, sodium adsorption ratio and sodium percentages indicate that most of the groundwater samples are inappropriate for irrigation. The SAR vary from medium (S2) to very high (S4) sodicity. Therefore, the water of the Djeffara aquifers of the northern Gabes is dominantly of the C4–S2 class representing 61.23 % of the total wells followed by C4–S3 and C4–S4 classes at 27.27 and 11.5 % of the wells, respectively. Based on the US Salinity Classification, most of the groundwater is unsuitable for irrigation due to its high salt content, unless certain measures for salinity control are undertaken. 相似文献