汶川─理县志留系茂县群无根钩状褶皱构造初步解析

钩状褶皱又称无根钩状褶皱，是区域变质岩中广泛发育的特有构造形态之一，与面状构造置换密切相关。对它的研究，有助于恢复大型褶皱形态和变质岩原岩产状。本文初步探讨了四川汶川─理县志留系茂县群中广泛发育的无根钩状褶皱的形态、产状、成因和与大型褶皱构造的关系。     

新疆构造运动期序及特征

新疆地域辽阔,地质构造运动复杂,特征各异。前人曾对新疆构造运动的划分及命名做了大量工作,但多有不一致,有些构造运动的划分或命名依据不足,因此失去了应有的代表性。现根据实际资料,对新疆地质构造运动重新归纳和认识,提出新疆境内构造运动可划分为11期32幕(次),其中前寒武纪6期、古生代2期17幕(次),中新生代3期9幕(次)     

冀东太古宙高级变质岩区若干地质问题的研究

在1∶5万区域地质填图及专题研究的基础上探讨了变质岩石中的岩浆侵位变形构造、褶皱构造及变形与变质作用的关系等三个方面的问题。研究表明冀东太古宙高级区变质岩石中不同程度地发育岩浆岩构造,包括在不同类型片麻岩之间所表现的穿切构造、基性岩墙中的矿物定向构造以及基性岩体边缘及其围岩的变形构造等,褶皱构造可分为表壳岩褶皱及片麻岩褶皱,高级区可能不存在大型的片麻岩褶皱,通过镜下特征矿物相的研究并结合野外变质基性岩墙的产状及特征,建立区域变质与变形作用的关系,从而为区域地质事件表的建立提供依据。     

西藏阿里札达盆地早更新世早期沉积及其古气候与古环境变化

综合分析了西藏阿里札达盆地早更新世早期的多种与气候环境变化密切相关的地质记录，结果表明该区早更新世早期的沉积可划分为3种不同的沉积相和4个岩性段；古气候与古环境变化可划分为4个阶段：（1）2．68-2．45Ma。为冲洪积相沉积。冻融褶皱开始出现，植被以乔木为主，主要为松、藜、蒿，属山地寒温气候；（2）2．45-2．11Ma，为冲洪积相，地层中冻融褶皱多呈扭曲状，草本植物迅速上升，显示出灌木草原气候特征，气候变得凉爽干燥；（3）2．11-1．49Ma，沉积相为冲洪积相-冰缘沉积相，以冰缘沉积相为主，冻融褶皱层开始增多，出现了喜凉的介形类化石。草本植物数量和种类达到最大，灌木也相对增加，显示气候进一步趋于干旱；（4）1．49-1．36Ma，为冰湖沉积相。地层中普遍出现冻融褶皱，喜凉的介形类化石丰度很高，草本植物有小幅下降，但蕨类植物增加幅度较大，显示了干冷草原气候特征。气候干旱寒冷。     

浙西北地区反转构造初步研究

通过浙西北地区金衢、乌马和杭嘉湖3个地震解译剖面及地表地质的综合分析,指出研究区在以T₂为主变形期的逆冲变形体制之前存在同方向的引张体制,并随后发生反转。通过计算反转比等综合分析,发现其总体反转程度自南东往北西方向逐渐变小,反映出反转后的褶皱冲断变形程度呈现自南东往北西方向变弱之趋势。     

Inclusion-trail geometry of albite porphyroblasts in a fold structure in the Sambagawa Belt, central Shikoku, Japan

The orientation of straight inclusion trails within albite porphyroblasts from basic schists has been measured around a north-closure fold, in the Besshi district of the Sambagawa Belt, central Shikoku, Japan. The porphyroblasts are aligned with their longest dimension parallel to both the subhorizontal, east–west-directed mineral lineation and to the fold axis. There is a systematic variation in inclusion-trail geometry between the upper (northern) and lower (southern) fold limbs. The shear sense deduced from quartz c-axis fabrics is top-to-the-west in the upper limb and top-to-the-east in the lower limb. Based on observed variations in porphyroblast inclusion trails, the structural history can be modelled as follows: (i) shear flow caused east–west stretching and folding of the metamorphic zonation; (ii) east–west ductile shear resulted in opposing senses of shear in the upper and lower limbs as the eclogite body situated in the core of the fold was extruded to the east.     

QUATERNARY FOLDING OF THE XIHU ANTICLINE BELT ALONG FORELAND BASIN OF NORTH TIANSHAN

Tianshan is one of the longest and most active intracontinental orogenic belts in the world. Due to the collision between Indian and Eurasian plates since Cenozoic, the Tianshan has been suffering from intense compression, shortening and uplifting. With the continuous extension of deformation to the foreland direction, a series of active reverse fault fold belts have been formed. The Xihu anticline is the fourth row of active fold reverse fault zone on the leading edge of the north Tianshan foreland basin. For the north Tianshan Mountains, predecessors have carried out a lot of research on the activity of the second and third rows of the active fold-reverse faults, and achieved fruitful results. But there is no systematic study on the Quaternary activities of the Xihu anticline zone. How is the structural belt distributed in space?What are the geometric and kinematic characteristics?What are the fold types and growth mechanism?How does the deformation amount and characteristics of anticline change?In view of these problems, we chose Xihu anticline as the research object. Through the analysis of surface geology, topography and geomorphology and the interpretation of seismic reflection profile across the anticline, we studied the geometry, kinematic characteristics, fold type and growth mechanism of the structural belt, and calculated the shortening, uplift and interlayer strain of the anticline by area depth strain analysis.
In this paper, by interpreting the five seismic reflection profiles across the anticline belt, and combining the characteristics of surface geology and geomorphology, we studied the types, growth mechanism, geometry and kinematics characteristics, and deformation amount of the fold. The deformation length of Xihu anticline is more than 47km from west to east, in which the hidden length is more than 14km. The maximum deformation width of the exposed area is 8.5km. The Xihu anticline is characterized by small surface deformation, simple structural style and symmetrical occurrence. The interpretation of seismic reflection profile shows that the deep structural style of the anticline is relatively complex. In addition to the continuous development of a series of secondary faults in the interior of Xihu anticline, an anticline with small deformation amplitude(Xihubei anticline)is continuously developed in the north of Xihu anticline. The terrain high point of Xihu anticline is located about 12km west of Kuitun River. The deformation amplitude decreases rapidly to the east and decreases slowly to the west, which is consistent with the interpretation results of seismic reflection profile and the calculation results of shortening. The Xihu anticline is a detachment fold with the growth type of limb rotation. The deformation of Xihu anticline is calculated by area depth strain analysis method. The shortening of five seismic reflection sections A, B, C, D and E is(650±70) m, (1 070±70) m, (780±50) m, (200±40) m and(130±30) m, respectively. The shortening amount is the largest near the seismic reflection profile B of the anticline, and decreases gradually along the strike to the east and west ends of the anticline, with a more rapidly decrease to the east, which indicates that the topographic high point is also a structural high point. The excess area caused by the inflow of external material or outflow of internal matter is between -0.34km² to 0.56km². The average shortening of the Xihubei anticline is between(60±10) m and(130±40) m, and the excess area caused by the inflow of external material is between 0.50km² and 0.74km². The initial locations of the growth strata at the east part is about 1.9~2.0km underground, and the initial location of the growth strata at the west part is about 3.7km underground. We can see the strata overlying the Xihu anticline at 3.3km under ground, the strata above are basically not deformed, indicating that this section of the anticline is no longer active.     

面元细分处理资料的分辨率定量评价

以永新工区高精度采集的地震资料为例,对高精度勘探的面元细分方法及细分处理资料的分辨率进行了评价。首先给出了面元细分的方法及面元细分对地震资料分辨率的影响,介绍了现有的一些分辨率计算方法。对于纵向分辨率,主要从λ/4传统薄层分辨率和高截频二个方面进行了讨论;对于横向分辨率,从菲涅耳带半径、防空间假频、Lindsey分辨率定义、考虑偏移孔径的分辨率等四个方面进行了分析、比较。通过研究,得出了有一定借鉴意义的结论:①在现有常规检波器条件下,面元细分处理对地震资料的分辨率影响较小,其变化不大;②在单道记录信噪比已较高的情况下,想通过提高覆盖次数来提高资料的分辨率,其提升空间有限;③就横向分辨率而言,考虑偏移孔径的计算方法,结果比较准确;④对于东部地区,从性价比上考虑,覆盖次数150,200已能满足要求,太高的覆盖次数没有从本质上改进资料的质量。     

Geological Evolution of Longhushan World Geopark in Relation to Global Tectonics

The South China fold belt has experienced a complex series of tectonic events that span 1.0 billion years of earth history. Longhushan (龙虎山) World Geopark is located on the Proterozoic suture between the Yangtze craton and Cathyasia block and highlights the long history of this belt. Collision of the Cathyasia and Yangtze cratons 1.0 billion years ago was associated with the formation of the Rodinian supercontinent where most of the planet's landmasses were amalgamated into one block. Jurassic through Early...     

松潘—甘孜褶皱带较场弧形构造特征及其大地构造意义

根据详细野外露头特征及显微构造特征将较场弧形带由南向北分为三个变形带:弧顶部、弧核部和弧翼部,不同分带具有明显不同的变形特征。由南向北变形特征由以塑性变形为主过渡为脆性变形为主,变质流体活动喜马拉雅构造期活动强烈,且向北逐渐增强;弧核部以叠瓦状逆冲构造特征分隔弧顶和弧翼部;弧翼部东西两翼变形及变质流体活动特征具有一定差异性。较场弧形带总体体现出多期次南北向挤压—张性应力变形构造特征,叠加北西—北北西向同构造期挤压变质运动,其宏观和微观变形特征与典型"走滑成因"模式弧形构造特征相异,为其大地构造成因机制的解释提出了新的限制条件。