JRC-JCS模型抗剪强度估算的平均斜率法

结构面对工程岩体的稳定性有着决定性的影响,结构面的抗剪强度参数是分析岩体稳定的关键的参数。本文回顾了结构面抗剪强度估算的JRC-JCS模型及其估算方法,提出了可快速估算结构面抗剪强度参数的平均斜率法,并通过对比分析阐明平均斜率法的优越性。     

降雨入渗时土坡中水土化学作用浅析

提出了土坡在降雨入渗过程中水土化学作用理论,简要分析其作用类型,阐述其作用主控因素,系统研究其溶解与沉淀作用、交换与吸附作用、氧化还原作用、以及水解与络合作用等水土化学作用机理,同时分析水土化学作用对土的强度与变形特性起到强化或弱化作用。     

半城市化地区形成的动力机制与发展前景初探--以浙江省绍兴县为例

本文分析了长江三角洲南翼绍兴县的区域条件和社会经济发展状况,归纳了其城市化的特征,说明该县也具有典型的半城市化地区特征。作者认为,在后发展国家,人口稠密地区的发展,必然会形成半城市化现象;这类地区的小城镇还将经历“自下而上”逐步逐级的集聚发展;分散状态的半城市化的行政区需要加强其中心城市建设,但需与上级区域的城镇体系发展相协调,不宜构造超越其服务区域的大型城市。     

探地雷达在祁连山多年冻土调查中的应用

探地雷达用于多年冻_十区的勘测一般通过钻孔和探坑进行直接对比来确定冻土层分布状况,但在野外工作中,钻孔资料一般很难得到,而探坑在有限的人力物力条件下也很难开挖,这给冻土层的野外确定带来很大困难.我们采用雷达探测资料寻找浅层地下冰深度来确定多年冻土上限的深度,企图能在没有现场对比资料的情况下寻找一种利用探地雷达探测多年冻土的简易方法.探测结果显示,通过地貌特征寻找浅层地下冰可能存在的典型地段进行雷达探测能很容易确定多年冻上上限的位置.2007年在祁连山区利用Pulsc EKKO Pro探地雷达进行了多年冻土的野外探测,结果显示:大雪山老虎沟海拔3 684 m(39.5907°N;96.4339°E)处多年冻土上限约为2.2 m,在冷龙岭北坡的水管河源头海拔4 053 m(37.5463°N;101.7709°E)至海拔3 907 m(37.5508°N;101.7752°E)处的多年冻土上限深度为2.5 m,在宁昌河源头沿河岸从海拔3 448 m(37.5649°N;101.84 55°E)至海拔3 377 m(37.5797°N,101.8377°E)处多年冻土上限为2.4 m,在走廊南山的观山河源头海拔3 468 m(39.2615°N;98.6715°E)处多年冻土上限深度在2 m左右.另外根据4个勘察区多年冻土特征地貌分布区的最低分布海拔总结得出,老虎沟地区为冻土下界分布最高地区,关山河源头为冻土下界分布最低地区.其原因主要是降水和植被的差异造成的结果,降水量大和植被良好的地区多年冻土下界的分布海拔就低,反之亦然.     

1975-2006年西藏羊卓雍错流域内湖泊水位变化对气候变化的响应

根据1975年地形图、1988年至2006年的TM、CBERS卫星遥感资料和1962-2006年逐年平均气温、降水量、蒸发量、相对湿度、风速和日照时数等气象资料以及1974-2005年的湖泊水位水文资料,对西藏羊卓雍错及其流域内的空姆错、沉错和巴纠错等4个湖泊的水位变化以及对气候变化的响应作了分析.结果表明:该区湖泊面积在近30 a来呈缓慢下降趋势,2005年与1975年相比,分别减少了46.55 km2、1.73km2、0.03 km2、6.01 km2,减少幅度分别为7.2%、4.3%、0.1%、13.6%.其主要原因是,由于羊卓雍错的湖水主要以降水补给为主,在降水增加、气温上升的情况下由于升温引起的湖泊蒸发效应超过降水增加导致的补给影响,是湖泊面积下降的主要原因.     

格陵兰冰芯氧同位素显示近千年气候变化的多尺度分析

用经验模态分解(EMD)方法对格陵兰冰盖GISP2冰芯古气候代用指标δ~ (18) O 序列进行分解, 结果表明: 格陵兰近10 ka来气候变化总趋势出现历时约490 a的中世纪暖期和历时约570 a的小冰期, 其间还存在次级的冷暖期变化;气候波动具有3 a、 6.5 a、 12 a、 24 a、 49 a、 96 a、 213 a、 468 a准周期, 既有NESO的因素, 也受制于太阳活动周期的影响. 第7, 第8内在模函数(IMF7, IMF8)波动振幅以及总体趋势分量res在1350A.D.出现明显的转型, 表明1350A.D.为中世纪暖期和小冰期的分界.     

Co‐seismic Faults and Geological Hazards and Incidence of Active Fault of Wenchuan Ms 8.0 Earthquake,Sichuan, China

Abstract: There are two co-seismic faults which developed when the Wenchuan earthquake happened. One occurred along the active fault zone in the central Longmen Mts. and the other in the front of Longmen Mts. The length of which is more than 270 km and about 80 km respectively. The co-seismic fault shows a reverse flexure belt with strike of N45°–60°E in the ground, which caused uplift at its northwest side and subsidence at the southeast. The fault face dips to the northwest with a dip angle ranging from 50° to 60°. The vertical offset of the co-seismic fault ranges 2.5–3.0 m along the Yingxiu-Beichuan co-seismic fault, and 1.5–1.1 m along the Doujiangyan-Hanwang fault. Movement of the co-seismic fault presents obvious segmented features along the active fault zone in central Longmen Mts. For instance, in the section from Yingxiu to Leigu town, thrust without evident slip occurred; while from Beichuan to Qingchuan, thrust and dextral strike-slip take place. Main movement along the front Longmen Mts. shows thrust without slip and segmented features. The area of earthquake intensity more than IX degree and the distribution of secondary geological hazards occurred along the hanging wall of co-seismic faults, and were consistent with the area of aftershock, and its width is less than 40km from co-seismic faults in the hanging wall. The secondary geological hazards, collapses, landslides, debris flows et al., concentrated in the hanging wall of co-seismic fault within 0–20 km from co-seismic fault.     

Diagenesis and Restructuring Mechanism of Oil and Gas Reservoir in the Marine Carbonate Formation,Northeastern Sichuan:A Case Study of the Puguang Gas Reservoir

Abstract: Based on the technology of balanced cross-section and physical simulation experiments associated with natural gas geochemical characteristic analyses, core and thin section observations, it has been proven that the Puguang gas reservoir has experienced two periods of diagenesis and restructuring since the Late Indo-Chinese epoch. One is the fluid transfer controlled by the tectonic movement and the other is geochemical reconstruction controlled by thermochemical sulfate reduction (TSR). The middle Yanshan epoch was the main period that the Puguang gas reservoir experienced the geochemical reaction of TSR. TSR can recreate the fluid in the gas reservoir, which makes the gas drying index higher and carbon isotope heavier because C2+ (ethane and heavy hydrocarbon) and 12C (carbon 12 isotope) is first consumed relative to CH4 and 13C? (carbon 13 isotope). However, the reciprocity between fluid regarding TSR (hydrocarbon, sulfureted hydrogen (H2S)?, and water) and reservoir rock results in reservoir rock erosion and anhydrite alteration, which increases porosity in reservoir, thereby improving the petrophysical properties. Superimposed by later tectonic movement, the fluid in Puguang reservoir has twice experienced adjustment, one in the late Yanshan epoch to the early Himalayan epoch and the other time in late Himalayan epoch, after which Puguang gas reservoir is finally developed.     

用标贯法对盘锦城区砂土液化进行等级分区

本文针对盘锦城区砂土液化不良地质作用,采用工程地质勘察中的原位测试——标准贯入试验法结合前人在此所作的地质调查资料和工程地质勘察资料,按照《建筑抗震设计规范》（GB5001-2001）相关规定,对盘锦城区的砂土液化进行相应的等级分区,对于盘锦市今后的工程建设具有实用意义。     

塔北地区构造和演化特征及其对油气成藏的控制

塔北隆起为塔里木盆地最富有油气的构造单元之一,其纵向上可分为中新生界和古生界两大构造层,上下特征有较大的差异性:古生界受到六条基底逆断层及其伴生断裂控制,构造格局可以划分为"四隆两凹"的构造单元:英买力低凸起、轮台低凸起、哈拉哈塘凹陷、轮南低凸起、草湖凹陷以及库尔勒鼻隆,该格局长期继承性发育,并逐层遭受剥蚀形成整个塔北残余古隆起,其上构造圈闭十分发育,同时由于暴露时间长,碳酸盐岩储层非常发育;中新生界整体上表现为南高北低的北倾斜坡形态,受到下伏古生界断层的后期活化影响,发育局部圈闭。塔北当前的构造格局在演化过程中主要形成于海西期,后期变化较小。研究表明,塔北地区构造演化大致经历了三大阶段:晚加里东-早海西期的稳定抬升剥蚀期,塔北在南倾的大斜坡背景上形成了北东-南西走向的轮南大型背斜,英买力低凸起初具雏形;晚海西-印支期的挤压抬升期,塔北隆起在原背景之上继承发展;燕山-喜山期为调整定型期,形成现今塔北地区构造格局。整体古生界构造格局形成早,稳定时间长,是库车油气和满加尔油气的长期指向区,控制了塔北地区油气分布,而多期的构造演化则控制了塔北地区油气藏不同时期的破坏和形成,也造就了目前塔北地区同时存在沥青、稠油、轻质油和天然气。