东南极格罗夫山：普里兹造山带中一个典型的泛非期变质地体

提要：距我国中山站以南约400 km的格罗夫山是普里兹造山带向南极内陆的延伸部分,其基底地体由约在920?910 Ma期间侵入的镁铁质－长英质火成岩和少量中元古代的沉积岩构成,这些岩石仅在泛非期（约570?500 Ma）经历了单相变质－构造旋回,因此是一个典型的泛非期变质地体。泛非期高峰变质作用并不象前人所认为的那样仅为中低压麻粒岩相,而是高达770?840?C、1.18?1.40 GPa,并在随后经历了近等温减压（约0.6 GPa）的P-T演化过程。大规模的A型紫苏花岗岩和花岗岩在同造山－后造山阶段侵位,并造成了麻粒岩地体近等压降温的P-T轨迹。这些花岗质岩石是由长期富集地幔的底侵物质（碱性玄武质岩石）经部分溶融而形成的。结合相邻地质体的研究资料,我们认为普里兹造山带可能发育在太古宙－格林维尔期基底地体之上,这些基底地体可能与新元古代（？）盖层卷入到了统一的泛非期造山作用过程。在泛非期造山作用过程中,地壳曾被增厚约达40?50 km,而后又经历了厚约20 km的地壳伸展垮塌和剥蚀。所以,普里兹造山带应代表东冈瓦纳陆块内部由板块缝合作用所形成的一条泛非期碰撞造山带。     

Mineralization during Collisional Orogenesis and Its Control of the Distribution of Gold and Other Deposits in the Junggar Orogen, Xinjiang, China

The Junggar orogen, Xinjiang, China, is an important part of the Ural-Mongolian orogen.The collisional orogenesis in this region occurred primarily in the Carboniferous and Permianwith an evolutional process of early compression and late extension. Mineralization of gold andother metals in the Junggar orogen occurred mainly in the Permian and in a few cases in theLate Carboniferous. The deposits are largely distributed in areas where collisional orogenesiswas intensive and formed in a transitional stage from compression to extension. Therefore, goldmineralization in the Junggar orogen is fully consistent with the collisional orogenesis in time,space and geodynamic setting. This indicates that the mineral deposit model of collisionalorogenesis is applicable to prospecting and study of ore deposits in the Junggar orogen.Furthermore, the factual distribution of gold and other deposits in this region is just the same asthe collisional orogenic model presents.     

新疆祁漫塔格维宝矿区西北部花岗闪长岩年代学、地球化学及其构造意义

维宝铜铅锌多金属矿床位于青海与新疆两省区交界处的若羌县境内,是近年来在新疆祁漫塔格地区新发现的具有大型远景规模的多金属矿床,本文对该矿床西北部含暗色包体花岗闪长岩开展了SIMS高精度锆石U-Pb定年和地球化学研究,结果表明该花岗闪长岩含有角闪石特征矿物,SiO2含量为60.74%~61.34%,K2O含量为3.01%~3.20%,A/CNK值为0.89~0.94,属于准铝质高钾钙碱性I型花岗岩;在球粒陨石标准化的稀土元素配分图上表现为右倾式,轻重稀土分馏明显,具有中等负Eu异常(δEu=0.56~0.59),微量元素以富集大离子亲石元素Rb、K和Th,明显亏损Ba、Ta、Nb、Ti等为特征。SIMS锆石U-Pb定年结果显示,花岗闪长岩结晶年龄为227.6±2.3 Ma(n=16,MSWD=0.02),形成于晚三叠世,是东昆仑祁漫塔格地区中—晚三叠世大规模中酸性岩浆侵入作用的产物。借助元素判别图解,结合矿床地质特征和区域构造演化特点,认为维宝矿区西北部花岗闪长岩形成的构造环境为后碰撞演化阶段,很可能是与深部壳幔混染有关的变火成岩部分熔融的产物。     

西藏冈底斯北带首例主碰撞造山期铜矿——林周县程巴矽卡岩型铜矿床地质特征、辉钼矿Re- Os同位素年龄及成矿意义

通过近十年的地质勘查,在冈底斯北带多座具有经济价值的矿床得到开发利用,该带已经成为西藏地区矿床勘查与研究的又一热点地区。程巴铜矿是冈底斯北带近年来新发现的唯一一例中-大型规模的富铜矿床。矿床为典型的富含石榴子石的矽卡岩型矿床,铜矿体主要呈似层状、脉状产于林布宗组角岩和多底沟组大理岩的层间构造带内,矿石中富铜,伴生钼、锌、金、银、铋。本文在矿床成矿地质背景和矿床地质特征研究的基础上,用Re-Os同位素方法测试辉钼矿,获得等时线年龄为58.49±0.43 Ma(MSWD=0.61),模式年龄加权平均为58.49±0.33Ma(MSWD=0.25),确定程巴铜矿是主碰撞期成矿作用的产物,程巴铜矿的发现证明在冈底斯成矿带主碰撞造山过程能够形成铜矿床。因此,主碰撞成矿阶段由深变浅的矿床组合模型应在前人研究的基础上修改为矽卡岩型Cu(Mo)矿+矽卡岩型Fe-Pb-Zn-Mo(Cu)矿+斑岩型Mo(W)矿。此外,辉钼矿中Re含量介于84.6×10~(-6)～461.3×10~(-6)之间,平均值为252×10~(-6),暗示程巴矿区物源具有壳幔混合的特征。     

碰撞造山带超高温变质作用及构造意义——以泛非造山带为例

超高温（≥900℃）变质作用发生在自太古代以来的各个地质历史时期,目前极可能也正发生在青藏高原地壳深部。同时,它也是以冈瓦纳为代表的超大陆在最终拼合时的显著标识,这一关联指示了超高温变质作用与碰撞造山带的密切关系。本文总结了东冈瓦纳内与泛非造山作用有关的典型超高温变质岩的分布、岩石学特征、峰期变质条件、P-T轨迹及形成时代,并简要介绍我们在柴达木地块西段新识别出的泛非期超高温变质作用的基本特征。结合东冈瓦纳超高温变质作用特征和造山带热模拟研究的新进展,本文获得以东冈瓦纳超高温变质作用为代表的碰撞造山带超高温变质作用的几点认识：1）东冈瓦纳麻粒岩地块中的超高温变质岩和普通麻粒岩记录了相似的变质年龄、P-T轨迹以及呈过渡变化的峰期温度,两者可能是同一构造事件的产物,共同组成一个高温-超高温变质岩单元;2）超高温变质作用在东冈瓦纳内部持续了至少超过30Myr,但未见呈大规模的同期或近同期基性岩岩浆出露,指示此处需要的长期热源不是地幔来源岩浆;3）虽然数值模拟能成功呈现加厚地壳被放射元素衰变热加热至超高温条件的情况,且加热及持续时间与东冈瓦纳超高温变质约束的结果相当,但是模拟中需要的高生热值暗示,在自然界中,完全只靠放射性元素衰变生热或许不能让碰撞造山带内达到超高温条件;4）碰撞造山带经历了长期的构造演化,这一过程中,造山带内地壳不太可能同时达到超高温变质条件,这一特征可能反映在P-T-t轨迹的差异上,对这些轨迹的系统研究有助于对超高温变质作用的构造-热过程的理解。     

吉林中部红旗岭北沟花岗岩锆石U-Pb定年、地球化学特征及其地质意义

对华北板块北缘碰撞造山带东段吉林中部红旗岭北沟花岗岩岩体进行了岩相学、地球化学和LA-ICP-MS U-Pb定年研究。锆石测年结果显示红旗岭北沟花岗岩的结晶年龄为263 Ma,形成于中二叠世晚期。北沟花岗岩为准铝质高钾钙碱性I型花岗岩类,富集轻稀土(LREEs)和大离子亲石元素(LILEs,Cs、Ba、K和Sr),亏损重稀土(HREEs)和高场强元素(HFSEs,Nb、Ta和Ti),同时显示埃达克岩的地球化学特征,为加厚镁铁质下地壳部分熔融的产物。花岗岩的侵位暗示了中二叠世晚期在吉林中部可能已经发生了华北板块北缘东段与松嫩地块的初始碰撞。     

A new interpretation for the interference zone between the southern Brasília belt and the central Ribeira belt,SE Brazil

In southeastern Brazil, the Neoproterozoic NNW–SSE trending southern Brasília belt is apparently truncated by the ENE–WSW central Ribeira belt. Different interpretations in the literature of the transition between these two belts motivated detailed mapping and additional age dating along the contact zone. The result is a new interpretation presented in this paper. The southern Brasília belt resulted from E-W collision between the active margin of the Paranapanema paleocontinent, on the western side, now forming the Socorro-Guaxupé Nappe, with the passive margin of the São Francisco paleocontinent on the eastern side. The collision produced an east vergent nappe stack, the Andrelândia Nappe System, along the suture. At its southern extreme the Brasília belt was thought to be cut off by a shear zone, the “Rio Jaguari mylonites”, at the contact with the Embu terrane, pertaining to the Central Ribeira belt. Our detailed mapping revealed that the transition between the Socorro-Guaxupé Nappe (Brasília belt) and the Embu terrane (Ribeira belt) is not a fault but rather a gradational transition that does not strictly coincide with the Rio Jaguari mylonites. A typical Cordilleran type magmatic arc batholith of the Socorro-Guaxupé Nappe with an age of ca. 640 Ma intrudes biotite schists of the Embu terrane and the age of zircon grains from three samples of metasedimentary rocks, one to the south, one to the north and one along the mylonite zone, show a similar pattern of derivation from a Rhyacian source area with rims of 670–600 Ma interpreted as metamorphic overgrowth. We dated by LA-MC-ICPMS laser ablation (U–Pb) zircon grains from a calc-alkaline granite, the Serra do Quebra-Cangalha Batholith, located within the Embu terrane at a distance of about 40 km south of the contact with the Socorro Nappe, yielding an age of 680 ± 13 Ma. This age indicates that the Embu terrane was part of the upper plate (Socorro-Guaxupé Nappe) by this time. Detailed mapping indicates that the mylonite zone is not a plate boundary because motion along it is maximum a few tens of kilometres and the same litho-stratigraphic units are present on either side. Based on these arguments, the new interpretation is that the Embu terrane is the continuation of the Socorro-Guaxupé Nappe and therefore also part of the active margin of the Paranapanema paleocontinent. The Brasília belt is preserved even further within the central Ribeira belt than previously envisaged.     

The role of collisional tectonics in the metallogeny of the Central Andean tin belt

The Inner Arc of the Central Andes, broadly corresponding to the Eastern Cordillera, is the location of a rich Tertiary and Triassic Sn–W–(Ag-base metal) metallogenic province, commonly referred to as the Bolivian tin belt. We propose that the Tertiary metallogeny, which generated most of the tin ores, was a direct consequence of discrete “collisions” between the South American plate and the Nazca slab and sub-slab mantle, during the ongoing Andean orogeny. Evidence supporting this proposal include: (1) the coincidence of the tin province and the Inner Arc in a marked “hump” in the Andean orogen, which may represent tectonic indentation; (2) the symmetry of the tin province with respect to the Bolivian orocline, the axis of which corresponds to the direction of highest compression; (3) the relative symmetry of the magmatism and tin mineralization with respect to this axis; (4) the concurrent timing of mineralization and compressional pulses; (5) the similar host rock geochemistry and ore lead isotope data, testifying to a common crustal reservoir; and (6) the striking similarity of the igneous suites, associated with the ore deposits to those from “typical” collisional orogens. A number of studies have called upon a persistent tin anomaly to explain the metallogeny of the region. We propose, instead, that the latter is better explained by periodic compressional interaction between the Farallon/Nazca oceanic plate and the South American continent. This led to the generation of peraluminous magmas, which during fractional crystallization exsolved the fluids responsible for the voluminous Sn–W mineralization.     

高喜马拉雅的三维挤出模式

作为喜马拉雅造山带变质核的高喜马拉雅杂岩带,是以高级变质岩石、普遍的深熔反应以及高温韧性变形为主要特征的热碰撞造山带.在高喜马拉雅平行造山的韧性伸展构造发现的基础上,建立高喜马拉雅挤出的3-D构造模式,并提出了挤出的动力学过程:(1)造成高喜马拉雅中弱和热物质产生的局部熔融阶段(46～35 Ma),(2)平行造山的韧性伸展和重力裂陷阶段(28～26 Ma开始),(3)韧性逆冲型剪切带形成阶段(＞626～23 Ma),(4) MCT和STD的形成造成的高喜马拉雅挤出阶段(23～17 Ma).