Hydrochemical characteristics of salt marsh wetlands in western Songnen Plain

According to classification system of wetland in Ramsar Convention, salt marsh belongs to inland salt lake formed by regional hydrogeologic and climatic conditions[1]. In western Songnen Plain, the most distinct characteristic of water environment in salt marsh wetlands is that many water bodies have high salt contents and pH values, so salt marsh wetlands are categorized as a special natural synthesis[2]. 1 Natural environment in western Songnen PlainThe Songnen Plain lies to the east of …     

松嫩平原西部盐沼湿地水环境化学特征

松嫩平原西部盐沼湿地水环境碱化程度高,水中的pH值普遍高于8.0,多数为苏打钠型水。在对本区盐沼基本水环境化学特征阐述的基础上,通过对水化学的基本变量CO₃^2-、HCO₃^2-、Cl^-、Ca²⁺、Mg²⁺、SO₄^2-、Na⁺和派生变量(Cl^-+SO₄^2-)/HCO₃^2-及Na⁺/(Ca²⁺ Mg²⁺)等的相关分析,得出各水化学变量之间的相关关系,并以pH值为分类基础得到了判别函数和判别区域图,对区域盐沼湿地水环境化学特征的研究方法作出了有意义的尝试。     

珠江三角洲滨海小流域离子化学特征及来源分析

在分析中山大学滨海小流域水循环综合试验基地内雨水、河水和地下水离子组分的基础上,讨论了该小流域内水体离子化学组分的特征及来源。结果显示:①河水中TDS变化范围为28.97～44.64 mg/l,平均值为33.90 mg/l;在离子化学组成中,阳离子以Na++K+为主,阴离子以Cl-和HCO3-为主;雨水中TDS的变化范围为0.88～26.07 mg/l,平均值为8.42 mg/l,离子含量变化幅度较大;地下水TDS变化范围为39.49～113.16 mg/l,均值为58.11 mg/l,约为流域河水的2倍,雨水的7倍;②海盐沉降中Ca2+、Mg2+、Na+、K+、SO42-的贡献率:雨季分别为6%、60%、47%、2%和15%,旱季分别为3%、41%、54%、2%、9%;③硅酸盐风化中,雨季:(Ca/Na)sil=0.31,(Mg/K)sil=0.21;旱季:(Ca/Na)sil=0.36,(Mg/K)sil=0.27;CO2消耗率为12.4 t/(km2.a);④河水中的NO3-和(SO42-)res主要来源于大气酸沉降,且具有旱季含量低、雨季含量高的特点;⑤R1潜水井受到一定程度的NO3-污染,NO3-的...     

玉龙雪山周边典型河流雨季水化学特征分析

2009 年5~10 月在玉龙雪山周边典型小流域白水河、三束河、哥吉河采集河水样品,水化学分析结果表明,三条河流河水均呈现弱碱性,主要离子组成表现为富集Ca²⁺+Mg²⁺和HCO₃^-+SO₄^2-,且以Ca²⁺和HCO₃^-为主,各类离子存在显著季节变化。离子来源分析表明,玉龙雪山周边小流域河水雨季主要受降水和岩石风化影响,大气降水对河水主要常规离子Na⁺、K⁺、Ca²⁺、Mg²⁺、SO₄^2-的贡献率为分别为23.44%,9.66%,3.10%,17.81%,10.48%。研究区碳酸盐岩的风化产物是河水离子组成的主要控制因素。     

柴达木盆地中部高Mg/Li盐湖卤水富镁物源探讨

为了查清那棱格勒河尾闾盐湖—一里坪、西台、东台和察尔汗盐湖别勒滩区段高Mg/Li卤水富镁的主控因素及成因,系统采集了柴达木盆地那棱格勒河水、流域围岩和尾闾盐湖卤水样品,进行水样、岩样元素含量及矿物组合分析。结果表明,河水阴阳离子含量特征为Na~+>Ca~(2+)>Mg~(2+)和Cl~->HCO~-_3>SO■;与河水相比,卤水Ca~(2+)和HCO~-_3含量降低,Na~+、K~+、Cl~-和SO■明显富集,二者具有相似的Mg~(2+)离子含量所占阳离子总量的百分比(～25%);与南海海水和青海湖湖水蒸发曲线对比,卤水的镁含量落在曲线上,说明卤水富镁是由河水输入、蒸发浓缩控制的,而非盆地古湖自西向东浓缩迁移的结果;通过那陵格勒河流域围岩矿物和镁含量分析,发现河水流经的围岩中沉积有含镁矿物(白云石、含镁方解石和阳起石),且镁含量高达0.6%～11.5%,说明高镁的岩石风化溶滤是引起尾闾盐湖卤水富镁的主因。     

青海可可西里东北部多秀湖和盐湖水化学特征研究

2016年3月系统采集了青海可可西里东北部多秀湖和盐湖的湖水及其入湖冰川融水。研究发现,两个湖泊湖水中离子含量均较高,主要阳离子含量顺序均为Na~+Mg~(2+)K~+Ca~(2+),主要阴离子含量顺序均为Cl~-SO_4~(2-)HCO_3~-CO_3~(2-);而入湖冰川融水的离子含量非常低。根据库尔纳可夫—瓦良什科水化学分类标准,多秀湖湖水属于硫酸盐型—硫酸镁亚型,盐湖湖水属于硫酸盐型—硫酸钠亚型。多秀湖和盐湖湖水Li—Mg—B的相关性均为正相关,说明两个湖泊中这3种元素的物质来源、搬运条件及富集环境具有很强的相似性。由于气候变暖导致大量矿化度低的冰川融水注入盐湖,矿化度较低的卓乃湖和库赛湖决堤湖水泄入盐湖,使得盐湖的面积较1997年扩大了5倍,湖水的矿化度降低了约10倍,而多秀湖近些年湖水矿化度变化较小。多秀湖湖水矿化度以及Li~+、Mg~(2+)和B_2O_3含量均较高,具有较好的资源潜在利用价值。     

基于MODIS数据的松辽平原土地退化宏观评估

该文利用植被指数、最小噪声化变换、纯净像元指数和匹配滤波等遥感信息定量分析方法,从MDDIS陆地观测数据中提取反映松辽平原土地退化状况的植被覆盖、盐碱化和沙漠化信息,实现土地退化制图及土地退化格局分析。MODIS数据及其定量分析技术,对干旱区与半干旱区土地退化的宏观监测具有重要作用。     

腾格里沙漠区盐湖物质成分研究

腾格里沙漠面积广阔 ,区内分布着数十个盐湖 ,盐湖面积大的为十余平方千米 ,小的仅为 0 .0 18km2 。盐湖卤水主要为湖表卤水 ,其矿化度较高 ,大部分盐湖卤水含盐量已达饱和 ,因而进入了自析盐阶段。盐湖卤水化学成分以 Na+ 、K+ 、Cl-、SO4 2 -、HCO3 -、CO3 2 -为主 ,占卤水总含盐量的 99% ,卤水中还有 B2 O3 、L i、I、Br等微量元素。盐湖盐类沉积有碳酸盐类、硫酸盐类和氯化物型盐类、主要盐类矿物为芒硝、钾芒硝、天然碱、泡碱、碳钾钠矾、石盐等。盐湖粘土矿物组合以蒙脱石的普遍存在为特征 ,含有少量的伊利石和水云母。     

外掺Cl对磷酸镁水泥离子溶出和孔结构的影响

通过测试不同Cl~-(NaCl)掺量磷酸镁水泥(MPC)浸取液中离子浓度及MPC硬化体的孔结构和吸水率,研究了Cl~-掺量和浸取时间对MPC硬化体平均孔径、孔隙率、孔径分布、孔体积分布、吸水率、MPC浸取液中Cl~-、Na~+、OH~-、Mg~(2+)、PO■和K~+浓度的影响,结果表明外掺Cl~-对MPC孔结构、离子溶出及吸水率有显著影响,当Cl~-掺量为1%时,MPC硬化体结构密实、孔隙率低、平均孔径小、吸水率小、MPC水化产物在水中的溶蚀量小。     

Composition, spatial distribution, and environmental significance of water ions in Pumayum Co catchment, southern Tibet

The chemistry of major cations (Mg2+, Ca2+, Na+, and K+) and anions (HCO3 ?, SO4 2?, and Cl?) in the water of Lake Pumayum Co and its inflow river was studied, revealing the obvious ionic difference among various inflow rivers and the lake. The chemical type of the lake water was Mg2+-Ca2+-HCO3 ?-SO4 2+, but the major ions of the main inflow rivers were Ca2+-Mg2+-HCO3 ?. In the lake inlet of Jiaqu River, the main inflow river, there was significant variance of water chemistry within the depth less than 2 m. However, it was almost homogeneous at other area of the lake. Therefore, with the evidence of distribution of water chemistry and oxygen isotope of lake water, a conclusion can be outlined that Jiaqu River had a distinct effect on the hydrochemistry of the water on the submerged delta, whereas this is not the case for other rivers. The Gibbs plot revealed that the dominant mechanism responsible for controlling chemical compositions of the lake water was rocks weathering in the drainage area. Ion ratios and ternary plots further explored the main processes controlling the water chemistry of the catchment, i.e., carbonate weathering, pyrite weathering, and silicate weathering. The different hydrochemistry characteristics between river water and lake water may result from the CaCO3 precipitation. The findings will benefit the explanation of the environmental significance of carbonate in paleolimnological studies in the lake.     

北京城市湿地时空演变及驱动力定量分析(英文)

The decision tree and the threshold methods have been adopted to delineate boundaries and features of water bodies from LANDSAT images. After a spatial overlay analysis and using a remote sensing technique and the wetland inventory data in Beijing, the water bodies were visually classified into different types of urban wetlands, and data on the urban wetlands of Beijing in 1986, 1991, 1996, 2000, 2002, 2004 and 2007 were obtained. Thirteen driving factors that affect wetland change were selected, and gray correlation analysis was employed to calculate the correlation between each driving factor and the total area of urban wetlands. Then, six major driving factors were selected based on the correlation coefficient, and the contribution rates of these six driving factors to the area change of various urban wetlands were calculated based on canonical correlation analysis. After that, this research analyzed the relationship and mechanism between the main driving factors and various types of wetlands. Five conclusions can be drawn. (1) The total area of surface water bodies in Beijing increased from 1986 to 1996, and gradually decreased from 1996 to 2007. (2) The areas of the river wetlands, water storage areas and pool and culture areas gradually decreased, and its variation tendency is consistent with that of the total area of wetlands. The area of the mining water areas and wastewater treatment plants slightly increased. (3) The six factors of driving forces are the annual rainfall, the evaporation, the quantity of inflow water, the volume of groundwater available, the urbanization rate and the daily average discharge of wastewater are the main factors affecting changes in the wetland areas, and they correlate well with the total area of wetlands. (4) The hydrologic indicators of water resources such as the quantity of inflow water and the volume of groundwater are the most important and direct driving forces that affect the change of the wetland area. These factors have a combined contribution rate of 43.94%. (5) Climate factors such as rainfall and evaporation are external factors that affect the changes in wetland area, and they have a contribution rate of 36.54%. (6) Human activities such as the urbanization rate and the daily average quantity of waste-water are major artificial driving factors. They have an influence rate of 19.52%.     

Groundwater quality and land use change in a typical karst agricultural region: a case study of Xiaojiang watershed, Yunnan

Taking the typical karst agricultural region, Xiaojiang watershed in Luxi of Yunnan Province as a research unit, utilizing the groundwater quality data in 1982 and 2004, the aerial photos in 1982 and TM images in 2004, supported by the GIS, we probe into the law and the reason of its space-time change of the groundwater quality over the past 22 years in the paper. The results show: (1) There were obvious temporal and spatial changes of groundwater quality during the past 22 years. (2) Concentrations of,SO42-,NO3-,NO2-,Cl-,and the pH value, total hardness, total alkalinity increased significantly, in which NH4+,NO3-, and NO2- of groundwater exceeded the drinking water standards as a result of non-point pollution caused by the expansion of cultivated land and mass use of the fertilizer and pesticide. (3) Oppositely, Ca2+ and HCO3- showed an obvious decline trend due to forest reduction and degradation and stony desertification. Meantime, there was a dynamic relation between the groundwater quality change and the land use change.     

巴丹吉林沙漠湖泊与地下水的补给来源及化学组成(英文)

Based on the analysis of ion chemical composition of lake water and shallow groundwater in the Badain Jaran Desert, this paper discussed the characteristics of ion chemical composition, spatial variation of lake water, and possible supply sources of lake water and groundwater in the desert areas. The results show that the pH, salinity, TDS and electrical conductivity of the lake water are greater than those of groundwater. The ion con-tents of water samples are dominated by Na+ and Cl?. Most of the higher salinity lakes are Na (K)-Cl-(SO4) type, and a few of low salinity lakes belong to the Na-(Mg)-(Ca)-Cl-(SO4)-(HCO3) type. Most of the groundwater is Na-(Ca)-(Mg)-Cl-(SO4)-(HCO3) type, attributed to subsaline lake, and only a few present the Na-Cl-SO4 type, flowing under saline lake. The pH, salinity, TDS and electrical conductivity in the southeastern lakes are relatively low, and there are slightly alkaline lakes. The pH, salinity, TDS and electrical conductivity in the northern lakes are much greater than those of the southeastern lakes, and the northern lakes are moderately alkaline and saline ones. In the southeastern part of the Badain Jaran Desert, the ion chemical characteristics of the lake water from south to north show a changing trend of sub-saline →saline→hypersaline. The changing trend of chemical compositions of ions in recent 9 years indicates that most of the ion contents have a shade of reduction in Boritaolegai, Badain, Nuoertu and Huhejilin lakes, which state clearly that the amount of fresh water supply is increasing in the 9-year period. The ion chemical composition of the lake water reveals that the flow direction of lake water is from southeast to northwest in the Badain Jaran Desert. The ion chemical composition, moisture content of sand layer water level height and hierarchical cluster analysis of the lake water and groundwater demonstrate that the lake water is mainly supplied by local rainfall and infiltration of precipitation in Yabulai Mountains and Heishantou Mountain, and the supply from the Qilian Mountains is almost impossible.     

不同形貌纳米二氧化锰对三价砷吸附性能及机理研究

以高锰酸钾和一水硫酸锰为原料,采用水热合成法,合成得到了花状和海胆状纳米二氧化锰吸附剂。研究了两种吸附剂对三价砷的吸附选择性、循环利用性及除砷机理。结果表明,阴离子对花状和海胆状吸附剂吸附三价砷的影响顺序略有不同,其分别为PO■ CO■HCO~-_3NO~-_3SO■Cl~-,PO■HCO■SO■CO■NO~-_3Cl~-;花状和海胆状二氧化锰经三次循环再生后的除砷率分别为65.5%和75.1%;两种吸附剂对三价砷的吸附机理主要为氧化吸附作用。     

塔里木河下游地下水位与水化学成分关联度排序分析

根据2001年塔里木河下游第四次生态输水前后地下水位、水质变化的监测和取样分析资料。运用灰色关联分析法。对塔里木河下游地表生态输水前、后的地下水位与地下水化学成分进行了关联分析。分析研究表明，生态输水对地下水质的影响比较明显。在关联排序中。阴离子的SO4^2-、Cl^-以及阳离子的Ca^2 、Mg^2 与地下水位变化的关联性较强；pH值与地下水位的关联度最低。仅为0．534；矿化度与地下水位关联度最高,达到0．863。     

松嫩平原内陆盐碱湿地的类型特征及分布规律

内陆盐碱湿地是湿地的重要组成部分,其类型、特征及分布规律的研究十分薄弱。松嫩平原是世界上内陆盐碱湿地发育的典型地区之一。本文参考国内外湿地分类标准,结合松嫩平原的特点,建立了内陆盐碱湿地的分类体系,将该区的盐碱湿地划分为2个湿地类,6个湿地型,13个湿地亚型,描述了各类型的主要特征,并阐述了松嫩平原内陆盐碱湿地的分布规律。这对我国的湿地分类系统是一个重要的补充,对进一步实施内陆盐碱湿地的保护、恢复和重建,促进松嫩平原社会经济和环境的可持续发展都具有重要意义。     

黄河三角洲湿地景观边界变化及其对土壤性质的影响

以1992年和2006年TM遥感影像为基础信息,运用滑箱扫描方法获得组分边界特征,分析了黄河三角洲景观总体变化,在此基础上,研究不同景观类型变化过程土壤容重、水分含量、全氮、全磷、有机质及土壤盐分离子Ca2+、K+、Mg2+、Na+的差异性,以揭示景观变化对湿地土壤性质的影响.结果表明,三角洲景观组分之间的边界趋于复杂化,部分耕地转化为柽柳(Tamarix chinensis)、芦苇(Phragmites australis)和翅碱蓬(Suaeda heteroptera),潮滩植被侵入滩涂.不同景观类型下的土壤性质差异不显著,但景观类型转化对土壤性质存在一定影响.农田转变为柽柳、芦苇、翅碱蓬过程中土壤容重降低;而滩涂转变为翅碱蓬后土壤容重提高.农田转化为林地和滩涂转化为灌丛过程中土壤含水量降低,而其他景观变化过程土壤含水量表现出增加的趋势.不同景观类型下土壤全氮、有机质、全磷含量均较低,且变化过程中土壤养分含量变化也较小.各景观类型变化过程中土壤Ca2+含量变化幅度最大;其他土壤盐分离子含量的变化因景观组分变化方向不同存在较大差异,但总体上看,不同景观变化过程下土壤盐分离子含量均具有较大变化.     

柴达木盆地西台吉乃尔盐湖矿区卤水水化学特征

西台吉乃尔盐湖位于柴达木盆地中部,矿区卤水中富含锂、钾、硼、镁等多种元素,极具开发价值。自2003年开始,矿区已开始进行大规模采卤,利用前人1959年和2001年两次勘查资料,从水化学角度分析和探讨了西台吉乃尔盐湖矿区未大规模采卤前卤水中各元素的分布规律和变化特征。研究表明,矿区西北部主要为氯化物型卤水,其余大部分地区基本为硫酸镁亚型卤水,我们推测地下卤水水化学类型的差异很可能与不同区域原始卤水的组成及补给水等因素有关。有益组分中,高含量的Li+、K+主要分布在矿区的西北部;B2O3的高含量区主要在矿区的中东部广大地区。赋存于孔隙卤水中K+、Ca2+、Mg2+、Li+、Cl-等元素的平均含量要高于晶间卤水;B2O3、Na+、SO42-等则低于晶间卤水;卤水矿化度、pH值和密度则相差不多。孔隙卤水在Na+、K+、Mg2+/Cl--H2O四元体系介稳相图中的投影点接近光卤石相区;湖表卤水和晶间卤水在Na+、K+、Mg2+/Cl-,SO42--H2O五元体系介稳相图中位于泻利盐、软钾镁矾和钾石盐的共结点附近,且分布比较集中;湖表卤水在演化阶段上存在较大差别;晶间潜卤水已普遍进入钾石盐析出阶段。研究还表明,西台吉乃尔湖湖水的水化学变化明显受季节变化的影响,而湖表卤水与地下卤水存在着一定程度的水力联系,这种联系的强弱和变化特征尚待进一步研究。     

黑河上游夏半年河水化学组成及年内过程

2006年5月至2006年10月在黑河上游扎马什克、祁连及莺落峡水文站逐日采集河水样,同期在七一冰川冰采集融水样,研究水化学组成、演化特征及其影响因素。样品分析结果表明：黑河上游山区,受人类活动影响较少,水中可溶性无机离子的含量比较低,主要受水岩作用过程影响。水文因素,特别是降水是控制水中化学物质含量季节变化的主要因素。受流域地理-地貌特征及水文差异影响,祁连水文站样品中Cl-,NO-3,SO2-4和Na+的含量相对较高,札马什克样品中Ca2+,Mg2+和HCO-3浓度较大,莺落峡的水化学组成介于扎马什克与祁连之间。在流域范围内,气候差异是引起水化学组成变化的主要因素。上游河水中的化学物质主要来源于碳酸盐溶解,也有部分硫酸盐的贡献,随径流演化,岩盐和硫酸盐的贡献逐渐占主要地位。     

洞庭湖流域不同水体中同位素研究

在洞庭湖流域内的长沙、汨罗、怀化对大气降水、地表水（河水）、地下水（泉水、井水）进行了取样,分析了流域内不同水体中稳定水同位素的变化特征以及它们之间的转化关系。研究发现地处亚热带季风区的洞庭湖流域,地表水、地下水中同位素继承了降水同位素冬半年富集、夏半年贫化的特征,但存在不同程度的滞后。同时,降水同位素的变化幅度及波动性明显大于地表水及地下水,而地表水、地下水中同位素较降水中要富集。流域内河水中同位素大致表现出随纬度升高而贫化的趋势,这主要受降水同位素场的影响。流域内长沙河水、井水、泉水中同位素组成均位于大气水线附近且分别大致位于一直线上,这说明大气降水是这3种水体的主要补给源。不同季节河水、井水、泉水中同位素组成与大气水线的比较则进一步反映出了不同水体在不同季节的转化关系。