适用倾斜滑面的刚性抗滑桩最小嵌固深度计算方法

为计算确定桩前滑面倾斜情况下加固边坡的抗滑桩最小嵌固深度,基于倾斜地面条件的抗滑桩计算地基系数法,确定嵌固段桩侧土层压力,同时采用塑性极限分析方法,推导与滑面倾角密切相关的嵌固段土层极限抗力,并根据桩侧地层最大压力不超过其极限抗力的条件,建立了抗滑桩最小嵌固深度计算方法,并确定了其与滑面倾角的关系。实例分析表明,抗滑桩最小嵌固深度随滑面倾角呈非线性增大,在倾角为10°～30°范围内变化显著;嵌固段地层黏聚力、内摩擦角和重度对抗滑桩最小嵌固深度均有明显影响,且呈负相关关系;本文方法所得桩体最小嵌固深度比传统考虑桩前滑面倾斜影响的方法约小18%。     

Spatially uniform specific discharge from headwater to river basins on the Chinese Loess Plateau

Hydrogeology Journal - Although there is a general consensus that spatial heterogeneity is ubiquitous in hydrological responses, it is common practice to assume a constant specific discharge among...     

双频激电法在河南某钼矿带进行快速找矿评价中的应用

文章主要介绍了运用双频道激发极化法在河南省豫西山区进行快速找矿工作中发现矿体的过程及在野外施工过程中应注意的几个问题。通过双频激电中梯测量,在工作区圈定了3处激电异常,通过该区地质资料,岩(矿)石物性特征以及化探次生晕资料对激电异常进行了综合研究分析,经过钻探验证,此异常与隐伏钼矿体和钼矿化有关。证明了双频激电法完全能适应在豫西山区进行快速找矿评价,并取得良好的效果。     

辽西四合屯脊椎动物集群死亡事件：火山爆发的灾变记录

辽西北票以ConfuciusornisSinosauropteryxZhangheotherium为代表的四合屯脊椎动物组合发现于义县组下部湖相沉积中,时代为早白垩世Barremian中期(J—K界线144 Ma)或Valanginian晚期(J—K界线136 Ma)。化石包括鱼类、两栖类、爬行类、鸟类和哺乳类及无脊椎动物和被子植物,孔子鸟类群和具“羽毛”的小型兽脚类恐龙共生。野外发掘表明,化石完整地保存骨骼硬体及羽毛、食物、胃石、卵等软体及生理组织,确认多次非正常生物集群死亡事件。在四合屯发掘剖面上,含化石正常沉积的湖相页岩与火山喷发事件形成的沉凝灰岩互层,中酸性火山爆发形成的环境突变效应是导致脊椎动物集群死亡的主要原因。     

VisualModflow模型在白涧铁矿区矿井涌水量预测中的应用

在分析确定白涧矿区水文地质边界条件的基础上,运用实测资料对Visu-almodflow模型进行识别和验证,同时修正了含水层的参数,修正后的模型较为可靠,可用于白涧矿区涌水量的预测。依据矿区奥灰含水层边界条件和渗透系数的不同,设计了-200m和-400m水平面不同边界及渗透系数三个方案对矿井的涌水量进行预测。结果表明:方案2的涌水量比较合理,能较真实的反映白涧铁矿矿体分布区水位疏降至-400m时的涌水量情况,预测其涌水量为7505m3/h。      

煤田三维地震叠前深度偏移技术及其应用

三维地震叠前深度偏移可实现反射点的正确空间归位和真正的共反射点叠加,减小菲涅尔带的影响范围,大大提高地震资料的分辨率。论述了三维地震叠前深度偏移的成像原理和关键技术,并应用于实际地震资料的处理中。结果显示,小断点显示较叠前时间偏移剖面更为清晰,提高了煤田三维地震探测细微构造的能力,取得了较好的地质效果。     

泥石流调查遥感解译新方法研究

文章在分析总结近年来遥感技术在地质灾害调查评价工作应用的基础上,针对存在的不足,就区域小流域泥石流地质灾害调查评价的遥感解译应用,提出了基于虚拟GIS和水文空间分析的遥感解译方法（RSVH）。该方法综合利用虚拟GIS、遥感图像数字处理技术和空间分析技术,将大尺度区域降级为较小尺度的空间逻辑单元。针对各单元应用遥感影像和高精度DEM数据创建三维虚拟场景。同时叠加地形、地质、岩性、土壤、灾害等具有丰富属性信息的图层,较好地解决了大尺度区域范围内遥感解译工作面临的困难。为小流域地质灾害的调查工作提供了新思路。     

黄骅坳陷埕北断坡不整合特征与油气成藏

黄骅坳陷埕北断坡处于歧口凹陷向埕宁隆起过渡的斜坡带上,发育多个不整合,这些不整合对该区的油气成藏起重要作用。利用地震资料,在剖面上将不整合划分为5种类型：褶皱不整合、断褶不整合、削截不整合、超覆不整合、平行不整合。其中平行不整合分布在凹陷区,褶皱不整合分布在基底,断褶不整合分布在大断裂下降盘,削截不整合分布在大断裂上升盘,而超覆不整合多分布在隆起斜坡区;利用测井资料,在纵向上将不整合划分为3层结构：不整合面之上岩石、风化粘土层及半风化岩石,由于每层结构的岩性与厚度不同,形成ACE型、ADE型、BCE型和BDF型4种岩性配置模式。不整合构成埕北断坡油气侧向运移的重要通道,同时在其之上形成超覆不整合油气藏,在其之下依靠风化粘土层遮挡形成削截不整合与褶皱不整合油气藏。勘探证实,研究区众多油气显示或油气藏均位于不整合面上、下50 m范围内。开展不整合与油气成藏关系研究,将拓宽黄骅坳陷隐蔽油气藏的勘探空间,对我国东部油气资源挖潜具有重要的理论与实践意义。     

Changes in soil organic carbon and its active fractions in different desertification stages of alpine-cold grassland in the eastern Qinghai–Tibet Plateau

In recent years, the desertification of alpine-cold grasslands has become increasingly serious in the Qinghai–Tibet Plateau in China, but it has not received the same amount of attention as has desertification in (semi)arid areas. Little is thus known about the change in soil organic carbon (SOC) during alpine-cold grassland desertification. To quantify the impacts of desertification on vegetation, SOC and its active fractions in alpine-cold grasslands, areas of light desertified grassland, medium desertified grassland, heavy desertified grassland, serious desertified grassland, and nondesertified grassland were selected as experimental sites in the eastern Qinghai–Tibet Plateau in China. The species number, height and coverage of vegetation were surveyed, and the soil particle fractions, SOC and SOC active fractions (including dissolved organic carbon (DOC), microbial biomass carbon (MBC), and labile organic carbon (LOC) were measured to a depth of 0–100 cm. The results showed that alpine-cold grassland desertification resulted in a significant reduction in vegetation cover, plant biomass, fine soil particles, SOC, DOC, LOC and MBC. The decreases in DOC, LOC and MBC were more rapid and apparent than were those in SOC, and the decrease in MBC was the most obvious among them. The rates of reduction in SOC concentrations accelerated as desertification progressed; most of the SOC was lost in the middle and later desertification stages, with lower losses during early desertification. The results indicate that active SOC fractions, particularly MBC, are more sensitive to desertification and can be used as sensitive indicators of desertification. Efforts to limit desertification and reduce SOC loss in alpine-cold grasslands should focus on early desertification stages and adopt strategies to prevent overgrazing and control the erosion of soil by wind.