马家沟矿断层赋存规律及其对生产的指导作用

笔 者 结合 工 作 实 践 ,概 述 了 马 家 沟 井 田 范 围 内 断 层 发 育 的 特 点 及 其 基 本 规 律 ;重 点 分 析 了F2断 层 的 赋 存 特征 ,简 要说 明 了根 据断 层赋 存 规律 对生 产 的指 导作 用 。     

钱家营矿首采区断层在剖面上的延伸规律

通 过对 开滦钱 家营 矿首采 区地 质资料 的综 合分析 ,得 出了 该 矿首 采区 断 层在 剖面 上 的变 化特 征 及规 律,并运用这些 规律 ,对未 采区进 行预 测、预报 ,正确 指导了 采掘 工程的 顺利 进行。     

大陆地壳（二）

全球地壳厚度等值线图(图6)显示了地壳厚度的双峰标度。海洋盆地的地壳厚度为6～7km(不包括4～5km的水层)，而大陆部分的平均厚度为39．7km。在海洋一大陆边缘的典型地壳厚度是30km，并向大陆内部逐渐增厚到40～45km。厚度超过50km的地壳局限在几个地区，包括中国西部的青     

由大地测量数据得到的犹他州沃萨奇断层带的全新世滑动速率：地震周期效应

在美国西部盆地山脉省的东部地区，GPS数据确定了一个宽大的现代变形带。使用覆盖在粘弹性下地壳／上地幔之上的弹性上地壳的有限元模型并结合地震周期效应，我们指出这些数据与现今的断层滑动集中在沃萨奇断层带上的模型是一致的。模拟的水平扩展速度是3．0～4．5mm／a，这也与全新世的地质数据相一致。这些模型是非一的，部分原因是大部分沃萨奇断层都处于地震周期的后期阶段，而这一时期跨断层的地表速度梯度均较低。     

论非均匀断层滑动弱化速率的标定

尝试用二维断层模型来描述断层在不稳定开始时滑动弱化速率的定标律。断层由一系列受滑动摩擦力作用变弱的片区组成，这些片区被牢固的障碍体所分隔。第一组断层包含不同尺度总滑动长度相同的片区的平均分布，而第二组断层由各种分形康托尔集合组成。破裂的整体活动性质由指数增长率λ来描述。对无限均匀的断层，系数λ由摩擦定律的弱化速率控制。在非均匀断层系中我们估算每一个断层的弱化速率，因为一个断层系的指数增长率λ与均匀断层是一致的。利用这种均匀断层的破裂过程，我们根据不同尺度均匀性断层和给定的系数λ来计算弱片区上的弱化速率。对于大尺度的破裂，弱化速率与尺度无关，长片区的开始过程类似于无限断层的破裂情况。本文考虑的是小尺度和所有不同几何形状的破裂，弱化速率记为α=β0^*／a，其中a为破裂尺度或者单个断层长度的一半，β0^*≈1．158。本文计算了滑动弱化距离Dc的值，在此基础上讨论了计算结果的物理含义，并给出了这个参数与尺度相关的可能解释。     

两种模拟方法(或加温方式)实验结果对比

进行单温阶加温和连续加温两种方式的模拟实验,前者相当于封闭体系,后者相当于开放体系.对比两者的油气产率,并探讨两者与自然界烃源岩生排烃过程之间的关系.实验结果表明,总气体产率和烃气产率开放体系均低于封闭体系;排出油量和总生油率开放体系均大于封闭体系.自然界烃源岩的生排烃过程可能是介于封闭体系和开放体系之间的一种状况.     

隐伏断裂的活动时代与影响带宽度分析-利用浅层地震和钻探资料

在现场实验探测的基础上，获得了最佳浅层地震反射探测参数. 数据处理过程中采用了滤波、编辑切除、预测反褶积、初至时拟合静校正和速度分析等技术，得到了高质量的浅层地震反射探测剖面. 利用地震剖面中反射波组信息、测线附近多个钻孔的地层和新年代学资料，揭示出探测到的断层带上断点位于埋深75~80 m, 距今约22万年的中更新世地层中. 从反射波组的连贯性、间断性、数量的增加或减少和形态变化等特点，结合钻探地质剖面等资料，认识到断层带上断点的宽度为100 m. 从反射波组的数量在剖面中的变化推测，隐伏断层陡坎的宽度为200 m，它在早更新世和中更新世早期是一条同沉积活动断层，中更新世晚期以来没有发生明显错断上覆地层的构造活动.      

The Activity of Major Faults and the Hydrothermal Alteration Zone at Tianchi Volcano of Changbaishan

It is found by field investigation that the near horizontal top surface of the brown or brick-red hydrothermai alteration zone varies obviously in elevation at different sections of the same layer on the caldera‘s inner wall of Tianchi, with that at the north section near the Tianwen Peak about 110 m higher than that at the south near the Jiangjun Peak in Korea. The top surface of the hydrothermai alteration zone can be taken as key horizon to tectonic movement. The difference indicates that the total uplift height of the NW wall of the Liudaogou-Tianchi-Jingfengshan fault, the principal fault trending NE at Tianchi, is bigger than that of the SE wall ever since the occurrence of hydrothermal alteration. This also explains why the topography in the northwest side of Tianchi is steeper and with more developed river system than in the southeast. The uplifting of the northeastern wall is bigger than that of the southwest along the principal NW-trend fault, namely, the Baishanzhen-Tianchi-Jince fault. It is observed from characters of hydrothermal alteration and the palaeoresiduum, that the recent vertical movement rate along the principal NE-trend fault is larger than that of the principal NW-trend fault. The two faults intersect at Tianchi, dividing the volcano into 4 blocks, with the uplift magnitudes decreasing successively in the order of the north, the west, the east and the south block. The biggest uplift of the north block corresponds well to the shallow magma batch in the north of Tianchi observed by DSS and telluric electromagnetic sounding, and etc. and they may be related with the causes.     

The Rotational Structure along the Eastern Segment of the Altyn Tagh Fault and Its Implications in Dynamics

As a result of the left-lateral strike-slipping of the Altyn Tagh fault in Neotectonic period, a contra-rotational structure, namely the Zhaobishan vortex structure, has developed at the juncture of the main Altyn Tagh fault and the northern fringe fault of the Qilian Mountains.Preliminary analysis on the deformation and evolution of the Zhaobishan vortex structure. In combination with the previous data, suggests that the tectonic transform between the Altyn Tagh fault and the northern fringe fault of the Qilian Mountains attributes to the deformation of the rotational structure. The existence of a series of rotational structures along the Altyn Tagh fault and on the northeastern edge of the Qinghai-Xizang(Tibet) plateau indicate that as the substance in the northern Qinghal-Xizang (Tibet) plateau moves clockwise around the eastern tectonic knot of the Himalayas, rotational structures become the principal mode on the northern marginal zone of the Plateau of transforming and absorbing tectonic deformation.     

A Preliminary Analysis of Relations Between Tectonic Deformation of Sedimentary Cover and Basement in Kuqa Depression

Study of seismic activity in the Kuqa area enables us to infer some possible active faults in basement from the epicentral distribution on different profiles. The relations between active faults in the basement and surface structures are analyzed and the difference between sedimentary cover and basement in their deformation characteristics and the genesis are discussed. The following conclusions have been drawn : ( 1 ) the epicentral distribution indicates that, the east Qiulitag and south and north Qiulitag deep faults in the basement correspond to the east and west Qiulitag anticlines, respectively. Moreover, deep faults also exist beneath the Yiqiklik and Yaken anticlines. It indicates that the formation of surface structures is controlled by deep structures; (2) A NE-trending strike-slip fault develops along the line from the western termination of Yiqiklik structure to Dongqiu Well 5 and a NW-trending active fault on the western side of Baicbeng. The two active faults across the tectonic strike are the main causes for tectonic segmentation of the Kuqa depression and possibly the cause for the middle segment (Kuqa-Baicheng) of the depression to be more shortened than both its eastern and western terminations; (3) The difference between the sedimentary cover and basement in their deformation characteristics depends mainly on the different properties of media between them.The lithospheric strength of the basement in the basin is fairly high, which determines the basement deformation to be mainly of brittle fracture seismic activity. While the strength of sedimentary cover is low, where there exist weak thin layers, such as coal and gyps. Under the effect of strong tectonic compression, the sedimentary rocks may undergo strong viscous or plastic flow deformation; meanwhile, an aseismic detachment may take place along the weak layers.