造山后脉岩组合的岩石成因——对岩石圈拆沉作用的约束

造山后脉岩组合是在寄主岩基冷却之后形成的，可能是造山带应力场转换的标志。昆仑造山带早中生代末期以及太行山-燕山造山带晚中生代花岗质岩基中广泛出露这种类型的脉岩，可划分为煌斑岩质，玄武质，闪长质，花岗闪长质．花岗质和富硅花岗质等5组。主元素和痕量元素分析表明它们是不同的原生岩浆固结的产物，相互之间不存在重要的分离结晶，同化混染和岩浆混合作用的关系，因而要求软流圈／岩石圈系统不同圈层的源区岩石同时达到部分熔融的条件。结合已有的高温高压实验，区域岩石圈结构和地质事件序列的分析，认为岩石圈拆沉作用是造山后脉岩组合形成的最合理触发机制。简单热模拟表明，软流圈窗顶界埋深达到一定深度时（例如昆仑造山带为82km），可以满足处于不同深度位置的中性麻粒岩，基性榴辉岩和地幔橄榄岩同时发生部分熔融。这时，岩石圈／软流圈系统可以有6～8个产生岩浆的位置。热的软流圈物质快速涌入软流圈窗，不仅触发地幔岩的减压熔融，也可能导致区域构造应力场由挤压转换为伸展，为岩浆的快速侵位创造了条件。所提供的岩石成因模型可以更合理地解释造山后脉岩组合的地质特征，主元素和痕量元素特征，也可以满足同位素体系变异所要求的条件。     

川西北磁组构演化及其揭示的应变特征

对龙门山褶皱冲断带北段前锋带至四川盆地边缘的川西北地区进行了磁组构研究.在江油和广元之间,沿着垂直于龙门山构造走向的4条采样路线,在18个采样点钻取了173个定向样品,样品采自侏罗纪和白垩纪砂岩及粉砂质泥岩.综合分析表明川西北磁组构反映的是新生代的变形,并在研究区域内总结出了3类磁组构:沉积磁组构、初始变形磁组构和铅笔状磁组构.除沉积磁组构之外的所有采样点样品的K1优势方向都是NE-SW向,说明研究区域的最大主压应力方向为NW-SE向,主要来源于龙门山褶皱冲断带.在垂直于龙门山褶皱冲断带构造走向上,从四川盆地到龙门山前锋,磁组构由沉积磁组构逐渐变为初始变形磁组构,直至铅笔状磁组构,说明盆地内部应变十分微弱,靠近造山带应变逐渐增强,且侏罗纪、白垩纪以来研究区的构造变形主要集中在造山带边缘或者还未传递到盆地内部.     

论龙门山飞来峰群

龙门山飞来峰群带状分布在映秀-北川断裂以东的狭长区域,在分布、构造线方向、内部变形以及组成等方面具有清晰规律性。在研究了飞来峰群的特征,并在实地调查和地震解释基础上,提出一种新的演化模式,认为飞来峰群主要是推覆作用的产物,并辅以滑覆作用;映秀-北川断裂在飞来峰的形成过程中发挥了重要作用。     

龙泉关韧性剪切带同变形花岗岩的构造特征及其独居石定年

龙泉关韧性剪切带强变形部位发育一系列平行剪切带走向展布的花岗岩脉体，构造变形特征表明它们可能是同变形花岗岩，是剪切作用下围岩部分熔融的产物。通过独居石电子探针定年，测得龙泉关韧性剪切带的年龄分别为：主变形幕发生于1877～1846Ma，第2个变形幕发生于1812-1782Ma，晚期1725Ma左右又经历了流体活动。龙泉关韧性剪切带的发生、发展与华北克拉通中部带古元古代晚期的变质事件同期，是东、西陆块碰撞的一个主要剪切带。     

北祁连山东段银硐粱早古生代高镁埃达克岩：地球动力学及成矿意义

银硐粱早古生代花岗闪长岩分布在北祁连造山带东段屈吴山地区,侵入于原阴沟群和前寒武纪变质岩系中。它与米家山、扁强沟、清凹山以及南华山花岗岩类共同构成长约220千米的构造—花岗岩带,沿 NW-NWW 向展布。地球化学研究结果表明,银硐粱花岗闪长岩具有典型的高镁埃达克岩的地球化学特征,它们具有富 Na 贫 K,SiO_2>56%,Al_2O_3>15%,Na_2O>4.0%(4.51%～4.92%),K_2O(1.96～2.77%),Na_2O/K_2O=1.63～2.40,属钙碱性侵入岩;高 Sr(599～691×10~(-6)),低 Y(6.3～8.1×10~(-6)),Sr/Y>40(81～94),Y/Yb>10(Yb<1.9×10~(-6)),La/Yh>20(22～45)以及相对于典型的埃达克岩,具有更高的 Mg~#(58～64,平均59)和相容元素 Ni(31～38×10~(-6))和 Cr(35～43×10~(-6))含量;富集轻稀土元素(LREE),亏损重稀土元素(HREE),(La/Yb)_N>10(16～32),轻微负 Eu 异常(Eu/Eu*平均为0.94),∑REE(85～112)×10~(-6);微量元素蛛网图显示,岩石富集大离子亲石元素(Rb、Ba、Sr),Nb-Ta 和 Ti 负异常,相对于 Ce 和 Nd,Sr 为正异常。由于银硐粱高镁埃达克岩是俯冲洋壳部分熔融的产物,因此,它的存在表明,老虎山弧后洋盆在早古生代早期发生了向北的俯冲作用。银硐粱 Cu-Au 成矿作用与高镁埃达克岩关系密切,表明在北祁连构造带东段寻找与埃达克岩有关的 Cu-Au 矿床是一个新的找矿思路。     

北祁连山东段海原一带海原群变质岩原岩恢复及其构造背景

对海原群的岩石组成、原岩性质和构造环境的研究表明,海原群中云母片岩、石英片岩的原岩是泥质岩、杂砂岩等,大理岩、石英岩的原岩为白云岩-灰岩、石英砂岩或硅质岩,绿片岩和角闪岩的原岩为基性火山岩或次火山岩,蛇纹岩的原岩为超镁铁质岩.变质沉积岩的形成构造环境判别结果表明,它们形成于活动大陆边缘,介于岛弧与稳定陆缘之间.变质基性火山岩主要亦介于岛弧拉斑玄武岩与板内玄武岩之间,部分显示洋脊玄武岩的特征.认为海原群形成于岛弧-弧后盆地的构造环境.     

Major Characteristics of the Lajishan Orogenic Belt of the South Qilian Mountains and Its Geotectonic Attribute

The Lajishan orogenic belt is one of the E-W-trending Caledonian erogenic belts within the Qinling-Qilian orogenic system. It was formed upon the Jiningian basement by intensive taphrogenesis. Its major characteristics comprise the prominent faulting along the north and south boundaries, the highly complicated petrological and petro-geochemical features of the volcanic rock series, and the development of a new type of ophiolite suite. In terms of tectonic analysis and the sequential analysis of tectonic settings of magmatic rocks, it is suggested that the Lajishan orogenic belt has undergone a complete "opening-closing" cycle, which can be further divided into 3 second-order "opening-closing" cycles. The composite characteristics of the "opening-closing" movement show that Laji Mountain is a typical fault orogenic belt. The fault orogenic belt is one of the most important types of intracontinental orogens. It is of critical theoretical and practical significance to summarize the characteristics and the     

A Large Ductile Sinistral Strike-Slip Shear Zone and Its Movement Timing in the South Qilian Mountains, Western China

There is a large ductile shear zone, 2 km wide and more than 3SO km long, in the South Qilian Mountains, western China. It is composed of volcanic, granitic and calcareous mylonites. The microstructures of the ductile shear zone show nearly E-W extending subvertical foliation, horizontal and oblique stretching lineations, shearing sense from sinis-tral to oblique sinistral strike-slip from east to west, "A" type folds and abundant granitic veins. Measured lattice preferred orientations (LPOs) of the mylonitic and recrystallized quartz of the granitic mylonite in the west segment suggest a strong LPO characterized by the dominant slip systems {1010} formed at high temperature (>650℃). K-feldspar of the mylonite shows an 39Ar/40Ar high-temperature plateau age of 243.3±1.3 Ma, and biotite, 250.5±0.5 Ma, which represent the formation age of the ductile shear zone. The 39Ar/40Ar plateau ages of 169.7±0.3 Ma and 160.6±0.1 Ma and the 39Ar/40Ar isochron ages of 166.99±2.37 Ma and 160.6±0.1 Ma of biot     

Differential exhumation of tectonic units and ultrahigh-pressure metamorphic rocks in the Dabie Mountains, China

A model involving buoyancy, wedging and thermal doming is postulated to explain the differential exhumation of ultrahigh-pressure (UHP) metamorphic rocks in the Dabie Mountains, China, with an emphasis on the exhumation of the UHP rocks from the base of the crust to the upper crust by opposite wedging of the North China Block (NCB). The Yangtze Block was subducted northward under the NCB and Northern Dabie microblock, forming UHP metamorphic rocks in the Triassic (240–220 Ma). After delamination of the subduction wedge, the UHP rocks were exhumed rapidly to the base of the crust by buoyancy (220–200 Ma). Subsequently, when the left-lateral Tan–Lu transform fault began to be activated, continuous north–south compression and uplifting of the orogen forced the NCB to be subducted southward under the Dabie Orogen (`opposite subduction'). Opposite subduction and wedging of the North China continental crust is responsible for the rapid exhumation of the UHP and South Dabie Block units during the Early Jurassic, at ca 200–180 Ma at a rate of ∼ 3.0 mm/year. The UHP eclogite suffered retrograde metamorphism to greenschist facies. Rapid exhumation of the North Dabie Block (NDB) occurred during 135–120 Ma because of thermal doming and granitoid formation during extension of continental margin of the Eurasia. Amphibolite facies rocks from NDB suffered retrograde metamorphism to greenschist facies. Different unit(s) and terrane(s) were welded together by granites and the wedging ceased. Since 120–110 Ma, slow uplift of the entire Dabie terrane is caused by gravitational equilibrium.