北京城市副中心典型海绵体地表水与地下水交互作用研究

海绵城市建设是推动绿色低碳城市建设及可持续发展的重要保障措施,可以有效解决城市内涝、水资源短缺等问题,对于城市生态文明建设具有重要意义。以北京城市副中心点、线、面3种不同类型海绵体作为研究对象,利用2018年5—9月枯、丰水期采集到的345组地表水和地下水同步连续监测数据,分析了典型海绵体的地下水水化学特征及其形成机制,探讨了不同含水层之间的水力联系。同时,以Cl^-为指示因子,结合其他水化学指标,研究分析了典型面状海绵体地下水与地表水之间的交互作用及影响程度。结果显示:在垂向上,埋深10 m和20 m含水层地下水之间联系密切,且受大气降水影响明显;埋深50 m和80 m含水层组地下水与其他含水层组无明显水力联系。在平面上,线状及面状海绵体地表水对地下水的影响距离为80~100 m;随着地层埋深的增加,地表水对地下水的影响程度减弱。     

晴隆锑矿和煤矿矿集区岩溶地下水环境质量评估

锑是环境中广泛分布、具有慢性毒性和潜在致癌性的典型毒害重金属,是一种新兴的全球性环境污染物。过去对锑的地球化学行为研究较多,但对岩溶地下水的环境质量影响的研究较少。选择锑矿和煤矿分布广泛的贵州晴隆县境内龙摆尾地下河为研究对象,对研究区的地表水和地下水的水化学特征和污染特征进行研究,以《生活饮用水卫生标准》(GB 5749—2006)和《地表水环境质量标准》(GB 3838—2002)中的Ⅲ类标准值为评价标准对该地区水质予以评价。结果表明:在锑矿未开采情况下,第四系碧痕营组地下水中锑的浓度较高,平均值为1.55μg/L,最高为6.32μg/L;锑、砷的迁移受氧化还原条件的控制;岩溶地下水整体来说水质符合生活饮用水标准,但碧痕营组水中锑、锰超标,龙潭组中节理裂隙水存在pH、锰超标情况;而煤矿开采污染的地表水中锰、铁的污染具有普遍性,含量均超过地表水环境质量标准的限值,且超标倍数较大。因此,该研究区岩溶地下水可直接作为饮用水源,而碧痕营组和龙潭组中地下水须做处理后才可饮用。     

基于因子 聚类分析的地下水中阳离子来源研究

于2020—2021年对某市20个监测井80份地下水样本进行了调查。采用因子分析和聚类分析法以地下水中阳离子浓度为研究对象进行溯源分析。结果表明,地下水中阳离子浓度会受到不同程度、不同类别的人类活动影响,其阳离子的来源呈现多样化的特点,其中铅、铜、铝、锰为农业面源来源,铵、钠、总硬度是工业来源,另外,砷、铁及锌等为自然来源,而在自然来源中出现的砷、铁阳离子的富集现象,很明显是受到了城镇化及工业化的影响。锌与氢离子可能是地下水中pH值受到人类活动的影响,或者是地表水的侧向补给带来的影响。     

典型城市地表水质综合评价方法研究

以中国10个典型城市2013年实测地表水水质资料为基础,运用内梅罗指数法、均值法、地表水质指数法(SWQI)3种评价方法对城市地表水质进行综合评价。结果表明:就评价指标而言,3套指标方案评价结果显著相关,最佳指标为DO、COD_(Cr)、NH_3-N、TP;就评价方法而言,内梅罗指数法是3种方法中的首选方法,SWQI法评价结果表现为过保护,均值法不能突出较差水质指标的影响。     

庞庄煤矿煤矸石淋溶液对周边水体影响分析

为研究庞庄煤矿张小楼煤矸石堆场淋溶液对其场地和周边地表水、地下水水质影响情况，围绕煤矸石堆场及周边采集13组水样做分析比对。结果表明，煤矸石堆场淋溶液对周边地表水体形成普遍污染，且污染物浓度随着污染距离增加逐步降低，一般化学污染指标主要包括溶解性总固体、硫酸盐、铁、锰、氨氮等，毒理学污染指标包括亚硝酸盐、氟化物、砷，超标倍率约为0.02~5.36。受距离及成井深度等因素影响，地下水体未遭受淋溶液明显的污染和影响。     

乌鲁木齐城市土壤与灰尘粒径空间分布特征

结合野外调研的基础,按照四分法采集乌鲁木齐市城市土壤与城市灰尘样品共计306个,利用激光粒度仪和ArcGIS分析了城市土壤与灰尘样品的全粒径(0.02～2 000μm)组成与空间分布特征。研究结果表明:乌鲁木齐城市土壤与灰尘在小粒径范围内空间分布差异不明显,城市土壤粒径主要集中在10～50μm,城市灰尘集中于100～250μm;城市重工业对城市土壤和灰尘小粒径颗粒分布影响更大,而城市商业、居住等为主的人类其他活动行为对大粒径颗粒影响更为显著。乌鲁木齐城市土壤可能对城市灰尘PM_1、PM_(2.5)、PM_(10)粒径分布的贡献比较突出,应从城市土壤、城市灰尘、颗粒物粒径空间分布、气象等因素综合考虑乌鲁木齐市大气污染的防控。     

畜禽养殖场污染状况监测与评价

对河南省三个有代表性的规模化养殖场污染物排放及其对周围环境的影响进行了调查、监测及评价,结果表明,畜禽养殖污染已成为农业面源污染的重要来源,对其周围地表水和地下水产生较大影响。     

四川省城市生活垃圾的组成及特性

对四川省典型城市生活垃圾的组成、元素分析及热值等实验结果进行分析,结果表明:典型城市生活垃圾具有厨余含量高(57.4%～66.1%)、渣土含量少(1.9%～11.7%)的特点;四川省城市生活垃圾热值介于4 200～5 500 kJ/kg之间,且大部分处在4 800～5 500 kJ/kg之间;攀枝花、绵阳和成都市金牛区城市生活垃圾热值较高,适合采用焚烧法,内江和遂宁的城市生活垃圾热值偏低,宜采用填埋的方法。     

北京市地下水污染源荷载影响评价

在阐述地下水污染源荷载影响基本概念的基础上,介绍了污染源荷载影响评价的3大要素:污染荷载等级、含水层敏感性及地下水价值,说明了评价体系、指标和方法及过程。根据主要污染源荷载分析,结合地下水环境现状,对北京市进行了分区,提出污染源管理措施。     

山东单县浅层高氟高碘地下水的水化学特征及成因分析

氟和碘作为人体必需的微量元素,过少或过多摄入都会影响人身健康,相较于缺氟、缺碘,高氟高碘地下水对人体的危害更加难以控制。该研究选择单县作为典型的水源型高氟高碘地区,通过对浅层高氟高碘地下水进行采样测试,采用箱线图、Piper图及双变量相关性分析等多元统计技术剖析了该区域浅层地下水的水环境特征;采用R型因子分析揭示了水化学成分之间的相互关系,探讨了该区浅层高氟高碘地下水的成因。结果表明:①单县浅层地下水中的氟化物和碘化物的质量浓度均值分别为1.2 mg/L和391 μg/L。②随着氟化物浓度的增加,水化学类型偏向于向HCO₃-Na型和HCO₃-Na·Mg型集中,而随着碘化物浓度的增加,水化学类型则倾向于以HCO₃-Na·Mg为主。③该区域强烈的蒸发浓缩作用是控制单县浅层地下水化学成分的最重要因子;萤石平衡控制作用是控制单县浅层地下水高氟背景的因子;水-有机沉积物相互作用是控制单县浅层地下水高碘背景的因子。     

Hydrochemical and geoelectrical investigation of the coastal shallow aquifers in El-Omayed area, Egypt

Monitoring and assessment of the coastal aquifers are becoming a worldwide concern for the need of additional and sustainable water resources to satisfy demographic growth and economic development. A hydrochemical and geoelectrical investigation was conducted in the El-Omayed area in the northwestern coast of Egypt. The aim of the study was to delineate different water-bearing formations, provide a general evaluation of groundwater quality, and identify the recharge sources in aquifers. Thirty-seven water samples were collected and chemically analyzed from the sand dune accumulations and oolitic limestone aquifers. Fifteen profiles of vertical electrical soundings (VESs) were obtained in the oolitic limestone aquifer to examine the variations of subsurface geology and associated groundwater chemistry. The groundwater reserves in the El-Omayed area are mainly contained in sand dune accumulations and oolitic limestone aquifers. The aquifer of sand dune accumulations contains freshwater of low salinity (average total dissolved solids (TDS)?=?974 mg/l). Groundwater of oolitic limestone aquifer is slightly brackish (average TDS?=?1,486 mg/l). Groundwater of these aquifers can be used for irrigation under special management for salinity control, and regular leaching as indicated by electrical conductivity and sodium adsorption ratio. Results of VES interpretation classified the subsurface sequence of oolitic limestone aquifer into four geoelectric zones, with increasing depth, calcareous loam, gypsum, oolitic limestone, and sandy limestone. Oolitic limestone constitutes the main aquifer and has a thickness of 12–32 m.     

Tidal along-shore groundwater flow in a coastal aquifer

Cross-shore interactions between the ocean and a coastal aquifer have been studied extensively, whereas the corresponding along-shore case has seldom been examined. This paper presents a numerical model that simulates two-dimensional groundwater flow averaged over the thickness of a coastal aquifer. The model is used to examine the essential features of tide-induced, along-shore effects on an aquifer adjacent to a cross-shore river. The results show that the tide, which fluctuates the water level in the river, induces groundwater table fluctuations and oscillating flows in the along-shore direction. This occurs even at locations much further inland than tidal cross-shore fluctuations can propagate. However, the magnitude of along-shore water table fluctuations and flow velocity at a given cross-shore distance decreases with the distance from the river in the same manner as cross-shore tidal fluctuations. The along-shore groundwater flow, together with the cross-shore flow, forms horizontal circulation and increases mixing of solute in the aquifer. Over a tidal period, a large amount of water exchange occurs at the river-aquifer and ocean-aquifer interfaces, leading to increased transfer of chemicals between the three water bodies. These results have implications for the management of waste discharge in estuaries and coastal aquifers.     

Time-lapse resistivity investigation of salinity changes at an ex-promontory land: a case study of Carey Island, Selangor, Malaysia

Time-lapse resistivity measurements and groundwater geochemistry were used to study salinity effect on groundwater aquifer at the ex-promontory-land of Carey Island in Malaysia. Resistivity was measured by ABEM Terrameter SAS4000 and ES10-64 electrode selector. Relationship between earth resistivity and total dissolved solids (TDS) was derived, and with resistivity images, used to identify water types: fresh (ρ ( e ) > 6.5 Ω m), brackish (3 Ω m < ρ ( e ) < 6.5 Ω m), or saline (ρ ( e ) < 3 Ω m). Long-term monitoring of the studied area's groundwater quality via measurements of its time-lapse resistivity showed salinity changes in the island's groundwater aquifers not conforming to seawater-freshwater hydraulic gradient. In some aquifers far from the coast, saline water was dominant, while in some others, freshwater 30 m thick showed groundwater potential. Land transformation is believed to have changed the island's hydrogeology, which receives saltwater pressure all the time, limiting freshwater recharge to the groundwater system. The time-lapse resistivity measurements showed active salinity changes at resistivity-image bottom moving up the image for two seasons' (wet and dry) conditions. The salinity changes are believed to have been caused by incremental tide passing through highly porous material in the active-salinity-change area. The study's results were used to plan a strategy for sustainable groundwater exploration of the island.     

Evaluation of hydrochemical changes due to intensive aquifer exploitation: case studies from Mexico

The impact of intensive aquifer exploitation has been observed in numerous places around the world. Mexico is a representative example of this problem. In 2010, 101 out of the 653 aquifers recognized in the country, showed negative social, economic, and environmental effects related to intensive exploitation. The environmental effects include, among others, groundwater level decline, subsidence, attenuation, and drying up of springs, decreased river flow, and deterioration of water quality. This study aimed at determining the hydrochemical changes produced by intensive aquifer exploitation and highlighting water quality modifications, taking as example the Valle de Toluca, Salamanca, and San Luis Potosi aquifers in Mexico's highlands. There, elements such as fluoride, arsenic, iron, and manganese have been detected, resulting from the introduction of older groundwater with longer residence times and distinctive chemical composition (regional flows). High concentrations of other elements such as chloride, sulfate, nitrate, and vanadium, as well as pathogens, all related to anthropogenic pollution sources (wastewater infiltration, irrigation return flow, and atmospheric pollutants, among others) were also observed. Some of these elements (nitrate, fluoride, arsenic, iron, and manganese) have shown concentrations above Mexican and World Health Organization drinking water standards.     

Evaluation of groundwater resources in a tiny Andrott Island, Union Territory of Lakshadweep, India

Lakshadweep is a group of 36 coral islands scattered in the Arabian Sea off the western coast of India. On such small tiny islands, groundwater is the only source of fresh water for the islanders. Due to the growing population on these islands, demand for fresh water is also increasing and on the other side the peculiar hydrologic, geologic and geomorphic features restrict the availability of groundwater. Therefore, a proper understanding of the groundwater condition is important in order to meet this increasing demand and also to formulate future development and management strategies. Detailed hydrogeological, geophysical and hydrochemical studies have been carried out to identify potential fresh groundwater resources and quantify vulnerable parts of Andrott Island, Union Territory of Lakshadweep. Systematic collection and analysis of hydrological, geophysical and hydrochemical data reveal that fresh groundwater is only available between 2.5 to 5.0 m depths and provide an early sign of deterioration in groundwater quality in the peripheral parts of eastern and western coasts of this island. It suggests immediate measures for arresting the deterioration in groundwater quality as well as augmentation for restoration of aquifer in some parts of the island.     

Hydrochemical analysis to evaluate the seawater ingress in a small coral island of India

The sustainable development of the limited groundwater resources in the tropical island requires a thorough understanding of detail hydrogeological regime including the hydrochemical behavior of groundwater. Detail analysis of chemical data of groundwater helps in assessing the different groundwater zone affected by formation as well as sea water. Groundwater and saline water interaction is better understood using groundwater major ion chemistry over an island aquifer. Multivariate methods to analyze the geochemical data are used to understand geochemical evolution of groundwater. The methods are successfully used to group the data to evaluate influence of various environs in the study area. Various classification methods such as piper, correlation method, and salinity hazard measurements are also employed to critical study of geochemical characteristics of groundwater to identify vulnerable parts of the aquifer. These approaches have been used to successfully evaluate the aquifer zones of a tiny island off the west coast of India. The most part of island is found to be safe for drinking, however some parts of island are identified that are affected by sea water ingress and dissolution of formation minerals. The analysis has successfully leaded to identification of that part of aquifer on the island which needs immediate attention for restoration and avoids further deterioration.     

An appraisal of subsurface geology and groundwater resources of Owerri and environs based on electrical resistivity survey and borehole data evaluation

The research was aimed at determining the depth to the watertable, aquifer thickness and subsurface geology of the studyarea thus revealing its groundwater distribution as well as its potential as a substitute to the surface water resources.Vertical electrical soundings were carried out in the study area with maximum electrode spread. The Schlumberger electrode configuration technique was adopted. VES data were processedusing Schlumberger analysis package. Lithologic logs of alreadyexisting boreholes in the study area were collected, evaluatedand comparison were carried out. The results reveal alternatinglayers of sands, sandstones, gravel and clay. The lithologiclogs revealed that the study area is underlain by coastal sands (Benin formation). The water table varies from 10–64 m and thickness of the aquifer ranges from 20–80 m. Results show that the study area is underlain by a thick extensive aquifer that has a transmissivity of 2.8 × 10^-2m² s^-1 to 3.3 × 10^-1m² s^-1 and storativity 1.44 × 10^-4 to 1.68 × 10^-3m s^-1 values. The specific yield is about 0.31.The sandy component of the study area forms more than 90% ofthe sequence, therefore the permeability, the transmissivity andthe storage coefficient are high with an excellent source of groundwater resources.     

Cleanup of fractured rock aquifers: Implications of matrix diffusion

As contamination moves through a fractured rock aquifer, it tends to diffuse from the flowing fracture water into the rock's essentially stagnant pore water. This process tends both to retard a contamination plume's advance through a fractured rock aquifer and to substantially increase the difficulty of purging contamination from the aquifer. A mathematical model has been developed to evaluate the potential impact of this phenomenon upon water quality restoration in fractured rock aquifers. The numerical modeling reveals that cleanup of fractured rock aquifers will, in many cases, require many decades, even centuries, to achieve, particularly where substantial improvements in water quality are sought. The parameters which most strongly govern the degree to which matrix diffusion prolongs the aquifer restoration process are the rock's matrix porosity, fracture spacing, and matrix diffusivity, the chemical identity of the contaminant(s), and the length of time the aquifer has been contaminated.Since sedimentary rocks tend to have both relatively high matrix porosities and matrix diffusivities, it can be particularly difficult to purge contamination from sedimentary rock aquifers. Crystalline rocks, in contrast, typically have lower matrix porosities and matrix diffusivities, and therefore undergo more rapid cleanup. However, even in crystalline rocks, attainment of very high degrees of water quality improvement may be problematic. Numerical modeling also indicates that conventional groundwater pump and treat programs are not likely to be very effective in speeding up aquifer restoration if the rate limiting step in the process is diffusion of contaminants from the rock matrix.     

Integrated approach for demarcating subsurface pollution and saline water intrusion zones in SIPCOT area: a case study from Cuddalore in Southern India

This paper deals with a systematic hydrogeological, geophysical, and hydrochemical investigations carried out in SIPCOT area in Southern India to demarcate groundwater pollution and saline intrusion through Uppanar River, which flows parallel to sea coast with high salinity (average TDS 28, 870 mg/l) due to back waters as well as discharge of industrial and domestic effluents. Hydrogeological and geophysical investigations comprising topographic survey, self-potential, multi-electrode resistivity imaging, and water quality monitoring were found the extent of saline water intrusion in the south and pockets of subsurface pollution in the north of the study area. Since the area is beset with highly permeable unconfined quaternary alluvium forming potential aquifer at shallow depth, long-term excessive pumping and influence of the River have led to lowering of the water table and degradation of water quality through increased salinity there by generating reversal of hydraulic gradient in the south. The improper management of industrial wastes and left over chemicals by closed industries has led surface and subsurface pollution in the north of the study area.