扬子地台西北缘前陆逆冲带及煤田构造特征

扬子地台西北缘前陆逆冲带(即龙门山逆冲带)的形成和演化控制着扬子地台内部及其西北缘煤炭资源的聚积和赋存。它可分为根带、中带、锋带三部分。根带无煤聚积,工业煤炭资源赋存在中带,锋带的煤系埋藏过深。前陆逆冲带内的煤田构造变形是适应前陆逆冲挤压应力作用的结果,以发育有冲断叠瓦扇、双冲构造、平行褶皱、斜歪褶皱、飞来峰、逆冲岩席、断夹块等构造样式为特征。前陆逆冲带的形成是特提斯构造域长期演化、沿三条缝合带发生三次碰撞的结果。      

高精度重磁勘探在推覆体下找煤中的应用

应用高精度重磁勘探方法解决在推覆体下找煤问题.利用磁异常研究辉绿岩体的赋存状态,肯定了推覆体的存在;根据重力异常及数据处理结果研究推覆体下煤系地层的分布,指出太山-许台重力低带是测区内找煤最为有利的靶区.高精度重磁勘探是推覆体下寻找煤系地层前期勘探的有效手段之一.     

挑坎体型对下游雾化影响的试验研究

以解决挑流消能工在泄洪期间为提高消能率而加重下游雾化问题为目标,探究不同体型挑坎的下游雾化特性。通过水力学模型试验,对典型的非对称舌型坎、标准舌型坎、扭面贴坎和连续坎的下游水舌风分布、下游溅水雨强和不同液滴体积分布以及挑流水舌水力特性与冲刷特性进行了研究。研究表明:①各种工况下,非对称舌型坎、标准舌型坎、扭面贴坎的下游水舌风风速均大于连续坎。②对于非对称舌型坎,其溢洪道轴线左侧溅水强度大于右侧,其雨强左右两侧峰值差值最大为5.625 g/(m 2·min);对于扭面贴坎,其溢洪道轴线右侧溅水强度更大,其雨强左右两侧峰值差值最大为45.125 g/(m 2·min)。③随着距离水舌入水点长度增大,大粒径水滴数量和体积占比均剧烈下降;连续坎和舌型坎的挑宽均随着角度的增加而增加;冲坑深度随着角度的减小而增大。④在挑坎合适边墙侧设置扭面贴角能改善下游雾化危害,同时适当增加挑角可以减弱下游冲刷破坏。     

Northward cooling of the Kuncha nappe and downward heating of the Lesser Himalayan autochthon distributed to the south of Mt. Annapurna,western central Nepal

We investigated the tectonothermal history of the Lesser Himalayan sediments (LHS), which are tectonically overlain by the Higher Himalayan Crystalline. Fission‐track dating and the track length measurement of detrital zircons obtained from the Kuncha nappe and the Lesser Himalayan autochthonous sediments in western central Nepal revealed northward cooling of the nappe and possible downward heating of the autochthon by the overlying hot nappe. Nine zircon fission‐track (ZFT) ages of the nappe showed northward‐younging linear distribution from 11.6 Ma in the front at Tamghas, 6 Ma in the central at Naudanda, and 1.6 Ma in the northernmost point at Tatopani. Thermochronological invert calculation of the ZFT length elucidated that the Kuncha nappe gradually cooled down (30 °C/Myr) at the front and rapidly cooled down (120 °C/Myr) at the root zone. In contrast, the ZFT age of the Chappani Formation, located just beneath the Kuncha nappe in the central part, demonstrated a totally reset age of 6.8 Ma, whereas the Virkot Formation, structurally far from the nappe, yielded a partially reset age of 457.3 Ma. This suggests that the LHS underwent downward heating, resulting in a thermal print on the upper part of the LHS; however, the thermal effect was not sufficient to anneal ZFT totally in the deeper part. Presently, the nappe cover is eroded and denuded from this area. Detrital zircons from the Chappani Formation in Tansen area to the south of the Bari Gad Fault did not show any evidence of annealing, suggesting that nappe never covered the LHS distributed to the south of the fault.     

Northward younging zircon fission‐track ages from 13 to 2 Ma in the eastern extension of the Kathmandu nappe and underlying Lesser Himalayan sediments distributed to the south of Mt. Everest

This study is concerned with the tectono‐thermal history of the Kathmandu nappe and the underlying Lesser Himalayan sediments (LHS) that are distributed in eastern Nepal. We carried out zircon fission‐track(ZFT) dating and obtained 16 ZFT ages from the eastern extension of the Kathmandu nappe, the Higher Himalayan Crystalline, Kuncha nappe, and the Main Central Thrust (MCT) zone. The ZFT ages of the frontal part of the Kathmandu nappe range from 13.0 ±0.8 Ma to 10.7 ±0.7 Ma and exhibit a northward‐younging tendency. These Middle Miocene ZFT ages indicate that the frontal part of the Kathmandu nappe remained at a temperature above 240 °C until the termination of its southward emplacement at 12–11 Ma. The ZFT ages of the LHS range from 11.1 ±0.9 Ma in the southern part of the Okhaldhunga Window to 2.4 ±0.3 Ma of the augen gneiss in the northern margin and also exhibit a northward‐younging age distribution. The ZFT ages show the northward‐younging linear distribution pattern (?0.16 Ma/km) along the across‐strikesection from the frontal part of the Kathmandu nappe to the root zone, without a significant age gap. This distribution pattern indicates that the Kathmandu nappe, the underlying MCT zone, and the Kuncha nappe cooled from the frontal zone to the root zone as a thermally united geologic body at a temperature below 240 °C. An older ZFT age (456.3 ±24.3 Ma), which was partially reset at the axial part of the Midland anticlinorium in the central part of the Okhaldhunga Window, was explained by downward heating from the “hot” Kathmandu nappe. The above evidence supported a model that southward emplacement of the hot Kathmandu nappe resulted in a thermal imprint on the upper part of the LHS; however, the lower part did not reach 240 °C.     

滇西牟定—香格里拉电性剖面及深部构造

通过对滇西NW—SE向牟定—香格里拉大地电磁测深剖面的反演并结合地质构造、小震精定位资料,综合分析了剖面经过地区的深部构造.在滇西北地区深部发育一规模巨大的近水平产出地壳高导层,此高导层从香格里拉一直延伸到永胜盆地以东,沿剖面水平延伸超过200km.地壳高导层又可分为两段,两段高导层在剖面上形成两个香蕉型相连的复合形态,高导层之上的高阻体则形成两个碗型相连的复合结构,碗型内部有向东倾斜的相对低阻带存在.滇西北地区整体构造格架可以解译为一套两个主推覆面构成的叠瓦式推覆系统,两个主推覆面高低起伏形成总长度超过250km的底部滑脱带.第一个主推覆面的长度超过150km,并在丽江东部上翘到接近地表,小金河断裂是其延伸到地表的主要破裂带.第二个主推覆面长度超过120km,过程海断裂后上翘并在永胜以东地区出露地表.根据反向低阻带影像,可以推断推覆体反冲构造发育,在玉龙山至丽江以东和永胜盆地西缘至平川盆地东缘形成两处冲起构造.推覆面在剖面上呈现出平缓-陡峭-再平缓-再陡峭的断坪和断坡相间的阶梯状结构.     

新疆博格达山北缘大龙口地区构造特征与油气勘探前景

大龙口地区位于新疆博格达山与准噶尔盆地的结合部位,属于博格达山北缘山前冲断带的组成部分,关于该区地下地质构造特征,长期以来缺乏清楚的认识。通过地表地质、地震和非地震资料的综合研究,纵向上以阜康逆冲断裂为界,将该区划分为下盘伸展构造系统和上盘逆冲推覆构造系统,前者为原地系统,构造变形较弱,保留有早二叠世裂谷的隆坳结构,对重新认识博格达山地区早二叠世的区域大地构造背景及演化具有重要意义;后者构造变形强烈,总体以自南向北的冲断推覆为主,并伴有一定的走滑扭动变形。经过多期构造运动,阜康断裂上盘勘探目的层已裸露,加之褶皱和断裂发育,油气保存条件差,勘探前景较差;而断裂下盘发育早二叠世残留凹陷,圈闭发育,油气保存条件好,勘探前景较好。     

新集矿区地应力场特征研究

矿井动力现象如巷道变形破坏、煤和瓦斯突出及煤层底板突水等都与地应力密切相关。应用水压致裂法对新集矿区的原地应力进行了测量,确定原地系统深部围岩的应力状态,即原地应力的量值和方向,研究获得了矿区地应力的赋存规律和基本特征。测量结果分析表明:新集矿区地应力场以水平应力为主导,属于构造应力场类型;垂直主应力和最大、最小水平主应力均随埋深的增加呈近似线性增加;最大水平主应力与最小水平主应力的比值范围是1.01~1.29,反映新集矿区受构造作用较恒定;测压系数的范围是0.98~1.3,随深度变化不明显;新集矿区受到F10断层东西向的拉张应力,最大水平主应力方向为近EW向。最后探讨了原地系统不同构造部位地应力方向差异的原因,初步分析认为,是受到阜凤推覆体的影响。      

福建三明吉口矿区推覆构造特征与控煤作用

根据矿区勘查和推覆构造研究资料,论述三明吉口矿区煤矿推覆构造特征与控煤作用,认为区内煤系地层为受推覆构造影响的“外来岩系”。以卷入地层及相关的岩体时代分析,认为区内拆离构造和推覆构造分别形成于印支期与燕山早期。     

南羌塘盆地中-新生代逆冲推覆构造样式及构造应力场特征

新生代印度板块与欧亚板块的持续碰撞挤压,造成南羌塘地块向南逆冲于拉萨地块之上,并在南羌塘地块内部形成了一系列的由北往南的逆冲推覆构造。然而,到目前为止,我们对这些逆冲推覆构造及夹持其间的褶皱变形的结构组成、构造样式、形成时代以及缩短量分布等问题仍存在很大的争议。本文在详细的野外调查基础上,对赛布错-扎加藏布断裂（SZT）,多玛-其香错断裂（DQT）,隆鄂尼褶断带（LF）及南羌塘与中央隆起带分界的肖查卡-双湖断裂（XST）进行了几何学、运动学分析,建立了精细的构造框架。我们认为这些断裂为始新世以来形成的同时期的叠瓦状逆冲推覆;并通过野外褶皱形态,结合层面、节理面、断层面滑动矢量的分析,识别出南羌塘盆地4期构造应力场：1） 代表中特提斯俯冲碰撞阶段的近S-N 向的挤压;2） 中特提斯碰撞后,随着班公湖-怒江缝合带的形成,南羌塘地区构造应力场转为S-N 向的伸展;3） 新生代印度板块向欧亚板块俯冲碰撞,青藏高原进入陆内变形阶段,南羌塘盆地内表现为NE-SW 向的挤压,形成本文提及的一系列逆冲推覆构造;4） 随着高原的持续隆升,约14 Ma南北向裂谷开始活动,应力场转为NWW-SEE 向伸展,形成双湖裂谷系。