江西省主要城市地下水资源及应急水源地遴选

江西各主要城市都是临水系而建,地表水资源是城市集中供水的主要水源。但是,为了应对突发事件很有必要在城市及其周边规划和遴选应急地下水源地。该文在分析阐述了各主要城市水文地质条件和地下水资源特征后．根据应急水源地的遴选原则,在全省11个主要城市中,确定了29个应急地下水源地,其可采资源总量为74781．372×10^4m^3／a。     

CSAMT法在高速公路长大深埋隧道勘察中的应用研究

CSAMT法是一套综合了MT和AMT各自优点的电磁自动采集和处理系统.本文介绍了CSAMT的原理、特点、工作方法和资料处理.该系统首次运用于高速公路长大深埋隧道勘察中，结合其它手段，成功解译出了隧道的软弱层、地下水及断层破碎带的位置，为划分隧道围岩类别提供了较好的依据，同时也为高速公路长大深埋隧道提供了一种新的勘察方法.     

安徽省河流和湖库型饮用水水源地水质评价

饮用水水源地的保护问题是关系国计民生的重大问题,饮用水水源地的水质问题越来越受到社会的关注.运用单因子标准指数法以及卡尔森指数法对安徽省境内91个县级以上的饮用水水源地的水质状况以及31个湖库型水源地富营养化程度进行了综合评价,并提出相应的防护措施.结果表明,全省91个饮用水水源地中水质达标的有83个,达标率为91.2%,其中,河流型水源地达标率为93.3%,湖库型水源地达标率为87%,地下水型水源地达标率为87%.     

三维可视化在CSAMT勘探中的应用

CSAMT法是一种强有力的地球物理勘探手段,具有测量迅速、探测深度大、信噪比高等优点,已被广泛应用于金属矿、油气田、地下水、以及地热田的勘探中.在CSAMT勘探资料解释方面,传统的二维电阻率断面很难清晰、直观地揭示3D(三维)地电结构的分布特征,为此应加强3D可视化应用技术的研究.本文详细的介绍了3D可视化的建模过程,将3D构造的建模分为空间曲面剖分、空间曲面拟合插值、空间曲面拓扑关系生成、3D结构网格剖分、属性建模等过程.并以一个CSAMT勘探实例,展现出3D可视化方法技术的突出优势.三维可视化可以多角度、多层面展现地下3D电性结构的分布特征,使我们更加清晰、直观地了解3D地质体的空间范围与几何形态.     

CSAMT法在半坡锑矿外围深部找矿中的应用效果

独山半坡锑矿石与围岩物性差异并不特别显著、矿体埋深较深,常规的物探方法无法满足目前的勘探要求.可控源音频大地电磁法(CSAMT)具有勘探深度范围大、分辨率高、地形影响和高阻层的屏蔽作用小,立体观测等特征,在深部找矿中发挥着重大的作用.本文首先概述了CSAMT基本原理和工作方法,在全面掌握了地质资料、物性参数的基础上,对独山半坡锑矿外围开展了CSAMT法勘探,通过应用Occam算法对CSAMT实测数据进行反演,成功地圈定了电阻率异常区域,有效地指导钻孔设计.物探异常钻探见矿,验证了CSAMT方法在深部找矿工作中的有效性,可为寻找同类深部锑矿提供指导和借鉴意义.     

可控源音频大地电磁法在隐伏煤矿区的应用

应用可控源音频大地电磁法在福建隐伏煤矿区进行了勘探研究.针对"三下找煤",在试验区做了CSAMT探测,分析原始数据,结合各矿区相关的地质资料,比对反演结果,进行了地层划分,圈定了靶区.研究结果表明,在隐伏煤矿区应用CSAMT法探测煤系地层有切实可行的效果.     

金沙江龙蟠变形体隐伏构造CSAMT探测与解译

龙蟠变形（岩）体位于金沙江宽谷河段右岸,规模巨大.此处区域主构造线为近SN向的中甸－龙蟠－乔后断裂带,地质构造背景极其复杂.为查清变形体内的隐伏构造,本次运用V6A多功能系统展开了CSAMT法探测研究.通过对CSAMT反演电阻率断面和钻孔、平洞等所获取的工程地质信息的综合解译分析,检验了CSAMT（V6A系统）法在高山峡谷区隐伏构造探测中的有效性和可靠性,解译成果全面清晰地揭示了冲江河断裂等在金沙江宽谷河段的展布格局,同时为龙蟠变形体稳定性评价提供了关键性地质资料.     

基于CSAMT和3D重磁地球物理模型综合解译相山石洞地区深部地质结构

本文利用CSAMT方法对相山石洞地区进行了深部地质结构探测.并尝试借助于先进的专业软件平台Oasis montaj对研究区已有的重磁数据生成3D重磁地球物理模型,从重磁模型中切取与实测CSAMT剖面大小、位置一致的密度切片和磁化率切片.将实测CSAMT剖面与密度切片和磁化率切片共同应用于解译石洞地区的深部地质结构.研究结果表明:CSAMT法较清晰的划分出了该地区的主要岩层的组间界面,刻画出了岩性界面的起伏形态,且与重磁资料共同识别出了3条已知断裂以及推测出了1条隐伏断裂;通过充分利用已有的重磁数据,不仅可以为CSAMT的地质解译提供依据,还可以提高地球物理数据的利用率降低地质工作的勘探成本.     

从CSAMT信号中提取IP信息探讨

CSAMT信号数据进行反演时,认为电阻率是一个与频率无关的实数,而实际上因为激电效应,地下可极化体的电阻率是一个与频率有关的复数.从CSAMT信号中提取激电信息可以加大激电法的使用范围,并可以提高CSAMT法勘探的精度.本文总结了国内外在这方面研究现状,介绍了从CSAMT法信号中提取激电信息的基本原理,并提出了未来值得深入研究的几个方面.     

利用积分方程法研究复杂三维地质结构CSAMT响应特征

由于复杂三维异常体模型与实际的地质结构更为接近,研究复杂地质结构的物理性质逐渐成为研究的热点.CSAMT三维模拟中,积分方程法因只需要对异常区域进行离散,具有占有内存少,运算速度快等优点.为了解复杂三维地质结构的CSAMT响应特征,本文先设置围岩为花岗岩体的含有倾斜断层等构造的三维复杂模型,利用积分方程法对它进行正演模拟并对模型的CSAMT响应特征进行分析.发现当异常体在垂直于测线方向的尺度发生变化时,在不同测线上观测的响应特征有所不同,进一步说明如果需要提高资料的解释效果,需要做三维勘探.最后基于油气藏电性结构特征,设置了含油构造的层状模型并进行正演模拟运算,含油构造模型的CSAMT响应特征表明,电性结构异常体的存在对电场的影响比对磁场的影响更敏感,这为我们以后的资料解释工作提供了最好采用电场总场资料而不用磁场总场资料的理论依据.     

煤层上覆地层含水不均匀性电法探测的可能性

煤田上覆岩层中含水直接对煤层的开采构成威胁，本文先从理论上阐述了电阻率勘探可以探测煤层上覆地层含水不均匀性的可能性，然后用简单的断层型薄层含水模型的CSAMT正演模拟结果展示出：地下900m深处，尽管只有20m厚的的含水岩层，但在电阻率剖面上该薄层的反映具有非常明显的特征，从理论上和数值模拟实例说明，一定深度内一定厚度的薄层含水性的电阻率法探测是可能的。     

某煤矿典型CSAMT法视电阻率曲线的一维模拟

了解煤矿开采区的地层地质情况,指明断层、破碎带、陷落柱等构造及其含水性,并分析其对开采过程中可能造成的安全威胁是煤矿安全生产的重要保证．可控源音频大地电磁测深(CSAMT)法是浅层地球物理勘探的一种有力的手段,可以用来探明从地表到地下1500米范围的地质情况．在开采区完成三维地震勘探,对构造有了较系统的控制后,利用电法CSAMT手段重点来分析构造及地层的含水及富水特性,是一种科学的工作流程．本文采用一维正演方法对该矿区典型的CSAMT视电阻率曲线进行模拟并与实际曲线进行了对比．通过大量的模型拟合,得到了较好的拟合效果,这对反演解释提供了有用信息。     

Quantifying ice storage in upper Indus river basin using ground-penetrating radar measurements and glacier bed topography model version 2

Ice reserve estimates is a fundamental prerequisite for water resources management. We selected the UIB (upper Indus river basin) as study area because it contains the most abundant mid-latitude glaciers outside the polar region, however, the ice reserve estimates remain unclear due to the harsh topography. In this study, we validated the parameters of the GlabTop2 model (Glacier Bed Topography version 2) using the ice thickness measured by GPR (ground-penetrating radar) and compared the “GPR-measured ice thickness and ice bed elevation” versus “the estimated results obtained from GlabTop2.” Integrated with IDW (inverse distance weighted) interpolated results of glaciers of various sizes, a reasonable parametric scheme (τ = 120 kPa and f = 0.8) of GlabTop2 was applied on vast amounts of glaciers in the UIB region. The GlabTop2 estimates indicated that the ice thickness of the UIB varied from 0 to 736.0 ± 110.0 m, with an average value of 74.5 ± 11.2 m. A significant spatial heterogeneity exists in the sub-basins. The Shyok, Shigar and Hunza that contain the most abundant ice reserve. Lesser quantities are stored in the Western Himalaya and Hindu Kush ranges, which account for 11.3 % and 6.7 % of the total ice reserve in the UIB, respectively. A total volume of 1162.4 ± 175.1 km³ of glacier can be converted to 1046.2 ± 157.6 Gt ice reserve; this is 13.6 times the annual average discharge obtained from the outlet of the Besham hydrological station. We aim to present estimates that can provide the baseline information for glaciology study of the Indus river.     

Improving hydrodynamic modeling of river networks by incorporating data assimilation using a particle filter

Numerical modeling is a well-recognized method for studying the hydrodynamic processes in river networks. Multi-source measurements also offer abundant information on the patterns and mechanisms within the processes. Therefore, improving hydrodynamic modeling of river networks through the use of data assimilation techniques has become a hot research topic in recent years. The particle filter (PF) is a commonly used data assimilation method and has been proven to be applicable to various nonlinear and non-Gaussian models. In the current study, an improved numerical hydrodynamic model for large-scale river networks is established by incorporating the advanced PF algorithm. Furthermore, the PF method based on the Gaussian likelihood function (GLF) and the method based on the Cauchy likelihood function (CLF) are compared for a complex river network scenario. The feasibility of the PF-based methods was evaluated through application to the Yangtze-Dongting River-lake Network (YDRN) by assimilating water stage data collected at six hydrometric stations during the entire hydrodynamic process in 2003. Additionally, the parameters used in the likelihood function, which affect the assimilation performance, also were explored in the current study. The study results found that the accuracy of the model-derived water stage data was improved when the PF-based methods are utilized, with improvement not only at the data assimilation (calibration) sites but also at three hydrometric stations not used in the data assimilation (i.e., verification sites). The highest average Nash-Sutcliffe Efficiency result for the six assimilation sites were 0.98 while the lowest summed root-mean-square-error result was 1.801 m. The comparison results also indicated that the CLF-based PF outperformed the GLF-based PF when high-accuracy observed data are available. Specifically, the CLF can effectively resolve the filtering failure problem and the dispersion problem of PFs, and further improve the accuracy of the filtering results for a river network scenario. In summary, the CLF-based PF method along with high-accuracy observation data shows promise to provide reliable reference and technical support for hydrodynamic modeling of large-scale river networks.     

A deterministic river temperature model to prioritize management of riparian woodlands to reduce summer maximum river temperatures

Increasing river temperatures are a threat to cold water species including ecologically and economically important freshwater fish, such as Atlantic salmon. In 2018, ca. 70% of Scottish rivers experienced temperatures which cause thermal stress in juvenile salmon, a situation expected to become increasingly common under climate change. Management of riparian woodlands is proven to protect cold water habitats. However, creation of new riparian woodlands can be costly and logistically challenging. It is therefore important that planting can be prioritized to areas where it is most needed and can be most effective in reducing river temperatures. The effects of riparian woodland on channel shading depend on complex interactions between channel width, orientation, aspect, gradient, tree height and solar geometry. Subsequent effects on river temperature are influenced by water volume and residence time. This study developed a deterministic river temperature model, driven by energy gains from solar radiation that are modified by water volume and residence time. The resulting output is a planting prioritization metric that compares potential warming between scenarios with and without riparian woodland. The prioritization metric has a reach scale spatial resolution, but can be mapped at large spatial scales using information obtained from a digital river network. The results indicate that water volume and residence time, as represented by river order, are a dominant control on the effectiveness of riparian woodland in reducing river temperature. Ignoring these effects could result in a sub-optimal prioritization process and inappropriate resource allocation. Within river order, effectiveness of riparian shading depends on interactions between channel and landscape characteristics. Given the complexity and interacting nature of controls, the use of simple universal planting criteria is not appropriate. Instead, managers should be provided with maps that translate complex models into readily useable tools to prioritize riparian tree planting to mitigate the impacts of high river temperatures.     

Quantifying the effects of stream discharge on summer river temperature

Abstract

Control of summer river temperature is needed for maintaining water temperature standards to protect aquatic biota and wildlife habitats. Given the fact that instream discharge, among meteorological and hydrological factors, may be the only one that can be practically managed, is it feasible to moderate summer river temperature through reservoir and streamflow regulations? An analysis is conducted to quantify the effects of the magnitude of instream flow on summer river temperature with weather as a reference. Relationships between water temperature and river discharge or flow depth are developed using a simplified model and adopting the concept of equilibrium temperature and bulk surface heat exchange coefficient. The relationships are validated against continuous 5-year field measurements at the central Platte River, Nebraska, USA. It was found that the variation of daily maximum water temperature with flow was stronger than that of daily mean. A critical discharge was obtained, which divides dramatic drop and slow variation in river temperature values. The existence of the critical discharge makes it possible to reduce or minimize the occurrence of daily maximum water temperature exceeding a standard at a river reach by increasing discharge to an achievable level. This study advances understanding of impacts of instream flow on summer river temperature and provides information useful in proper planning and design of reservoir operations and streamflow management.     

沿河开发建筑场地之隐伏沙洞的电阻率层析成像

采用电阻率层析成像二维测量的方法,对河南省三门峡市沿河开发的建筑场地进行了勘探,获取了地下隐伏沙洞的准确位置、埋藏深度、含水情况、尺寸大小等。说明电阻率层析成像二维测量的方法在地下隐伏沙洞的探测中是行之有效的;地下隐伏沙洞在没有水体存在时,电阻率层析成像二维测量成果图中反映的一般都是高阻异常封闭圈。如果有水体存在,其异常则表现为低阻异常封闭圈。     

The job of the river

Earth scientists have traditionally conceptualized rivers and streams as geomorphic machines, whose role is to transfer sediment and to sculpt the landscape. Steady‐state relationships between sediment supply and transport capacity have traditionally been considered normative in fluvial systems. Rivers are hydrological entities, however, whose function is to redistribute excess moisture on land. The geomorphic work of the river – erosion, transport, deposition, etc. – is a byproduct of the hydrological job of the river. There is therefore no reason to expect any particular relationship between sediment supply and transport capacity to develop as a normative condition in fluvial systems. The apparent steady‐state equilibrium slope adjustments of rivers are a byproduct of four basic phenomena: (1) hydraulic selection, which favors channels and branching networks over other flux patterns; (2) water flows along the available path of least resistance; (3) energy dissipation; and (4) finite relaxation times. Recognizing converging trends of stream power or slope and sediment supply as common (but far from inevitable) side effects rather than self‐regulation has important implications for interpreting and predicting fluvial systems, and for river management and restoration. Such trends are variable, transient, contingent, and far from universal. Where they occur, they are an emergent byproduct of fundamental physical mechanisms, not a goal function or attractor state. Copyright © 2009 John Wiley & Sons, Ltd.     

含激电效应的CSAMT一维正演研究

地电体对频率域电磁波激发源的响应为电磁感应和激电效应的综合响应.传统CSAMT法进行数据正反演时认为大地介质电阻率是与频率无关的实数,而实际上因为激电效应,地下可极化体的电阻率是一个与频率相关的复数.为推进二者总体响应研究,并扩展激电法的应用范围,同时提高电磁法勘探的精度,本文基于Dias模型,以复电阻率代替不考虑地电体极化效应的直流电阻率,对CSAMT场源一维层状模型进行了正演模拟,为提取CSAMT信号中所含激电信息提供理论基础.结果表明,考虑激电参数后,视电阻率及相位响应曲线出现明显异常（包括远场、过渡场、近场）;极化前后振幅比值异常峰值、相位差值异常峰值可直观体现激电异常;异常峰值与极化层层厚、埋深以及电阻率变化有连续的对应关系.认为从频率域电磁法信号中提取激电信息有乐观的前景.