Archean Basement and a Paleoproterozoic Collision Orogen in the Huoqiu Area at the Southeastern Margin of North China Craton: Evidence from Sensitive High Resolution Ion Micro-Probe U-Pb Zircon Geochronology

This paper reports sensitive high resolution ion micro-probe U-Pb zircon ages for the ＂Huoqiu Group＂ and granitoids of the Early Precambrian basement in the Huoqiu area, southeastern margin of the North China Craton. The ＂Huoqiu Group＂ is similar in rock association and metamorphism to the khondalite series, apart from it containing considerable amounts of banded iron formation. All detrital zircons from the ＂Huoqiu Group＂ meta-sedimentary rocks are 3.0 Ga and 2.75 Ga, without any 2.5 Ga and younger ones, as is commonly found in Paleoproterozoic khondalite series in other areas of the North China Craton. In the Huoqiu area, 2.75 Ga and 2.56 Ga granitoids have also been identified. This basement assemblage underwent strong metamorphism during the late Paleoproterozoic （-1.84 Ga） tectonothermal event that is widely developed in the North China Craton. Thus the formation time of the ＂Huoqiu Group＂ can be constrained between 2.75 and 1.84 Ga in terms of detrital and metamorphic zircon ages. It is considered, combined with regional data, that there may be a Paleoproterozoic collision orogen extending in a NWW-SEE direction to the southern margin of the North China Craton.

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.

Isotope Geochronologic and Geochemical Constraints on the Magmatic Associations of the Collisional Orogenic Zone in the West Kunlun Orogen, China

The Jiajiwaxi pluton in the southern portion of the West Kunlun Range can be divided into two collision-related intrusive rock series, i.e., a gabbro-quartz diorite-granodiorite series that formed at 224±2.0 Ma and a monzonitic granite-syenogranite series that formed at 222±2.0 Ma. The systematic analysis of zircon U-Pb geochronology and bulk geochemistry is used to discuss the magmatic origin （material source and thermal source）, tectonic setting, genesis and geotectonic implications of these rocks. The results of this analysis indicate that the parent magma of the first series, representing a transition from I-type to S-type granites, formed from thermally triggered partial melting of deep crustal components in an early island-arc-type igneous complex, similar to an I-type granite, during the continental collision orogenic stage. The parent magma of the second series, corresponding to an S-type granite, formed from the partial melting of forearc accretionary wedge sediments in a subduction zone in the late Palaeozoic-Triassic. During continued collision, the second series magma was emplaced into the first series pluton along a central fault zone in the original island arc region, forming an immiscible puncture-type complex. The deep tectonothermal events associated with the continent-continent collision during the orogenic cycle are constrained by the compositions and origins of the two series. The new information provided by this paper will aid in future research into the dynamic mechanisms affecting magmatic evolution in the West Kunlun orogenic belt.

The Discovery of Deep High-Resistivity Block and Inadequately Consolidated Magma Chambers in Gaoligongshan Oblique Collisional Orogen and its Tectonic Implications

Objective The Gaoligongshan oblique collisional orogen is located in the southern section of the Hengduan Mountains, and belongs to one of the main Late Yanshanian-Himalayan oblique collisional orogens in the Sanjiang area. Many researchers have studied the geology, geochemistry and geophysics of this region, and many research achievements have been obtained from deep geophysical exploration of the region, especially using the magnetotelluric （MT） sounding technique. However,

Paleomagnetism of Metamorphosed Sudbury Dykes, Canada: Relevance to a Theory of Crustal Shortening across the Grenville Collisional Orogen

The 1.235 Ga ESE-trending Sudbury dyke swarm cuts Paleoproterozoic to Archean rocks,but at its SE end becomes deformed and metamorphosed by the;Ga Grenville orogen,a result of collision between Laurentia

Late Proterozoic Colisional Orogen and Geosuture in Southeastern China:Petrological Evidence

The Jiangshan-Shaoxing fracture belt(JSFB)is a Late Proterozoic geosuture due to island arc-continent collision in South China,The Cathaysian Block(CT),lying on the southeast side of JSFB,is composed of green schist-amphibolite complexes in the form of a series of tectonic flakes. On the northwest side of JSFB,which is located in the border area of Zheijiang,Jiangxi and Ahhhi provinces(abbreviated as ZJP-JXP-AHP),are distrbuted and ophiolite suite and other rocks,constituting the Jiangnan ancient island arc(JN)on the southeast margin of the Yangtze Block(YZ).The collision between JN and CT at-0.9Ga ago led to the folding of JN.followed by the intrusion(-0.9-0.8Ga ago)of many dioritic and ultramafic stitching plutons along the fracture belt.As a result,the basic Precambrian tectonic framework of southeastern China was shaped.

Geochemical characterization of Granitoids in Katchuan Irruan area: further evidence for peraluminous and shoshonitic compositions and post-collisional setting of granitic rocks in the Precambrian Basement Complex of Nigeria

Petrographic studies on Granitoids from Katchuan Irruan and adjoining areas,southeastern Nigeria,has shown that they are garnetiferous biotite granite,aplitic granite,porphyritic hornblende biotite granite,porphyritic muscovite biotite granite,weakly foliated leucogranodiorite and simple pegmatite.They are closely associated with the Precambrian Basement Complex rocks which they intruded.Modal analysis shows that the rocks consist of quartz(10%-25%),oligoclase(10%-30%),K-feldspar(15%-35%),biotite(3%-25%),with occasional garnet,hornblende,muscovite,and accessory chlorite,haematite and magnetite.Geochemical data indicates that the rocks are generally shoshonitic,alkali-calcic to calcic,ferroan and peraluminous.They are enriched in large ion lithophile elements as well as high field strength elements(Hf,Ta,Yb,Sm,Zr and Y).Their trace elements and REE patterns are similar,indicating that they are co-genetic.They are characterized by high fractionation factor(La/Yb)N(3.04-228.44)and pronounced negative Eu anomalies(Eu/Eu*)(0.23-0.71).Their overall geochemical features indicate that they were most likely derived from partial melting of crustal materials in an orogenic(post-collisional)tectonic setting.They are therefore related to the Pan-African granites,otherwise known as the Older Granites which were emplaced during the Pan African orogenic event.

The final collision of the CAOB:Constraint from the zircon U-Pb dating of the Linxi Formation,Inner Mongolia

The Linxi Formation occupies an extensive area in the eastern Inner Mongolia in the Central Asian Orogenic Belt （CAOB）. The Linxi Formation is composed of slate, siltstone, sandstone and plant, lamellibranch microfossils in the associated strata. Major and trace element data （including REE） for sandstones from the formation indicate that these rocks have a greywacke protolith and have been deposited during a strong tectonic activity. LA-ICPMS U-Pb dating of detrital zircons yield ages of 1801 to 238 Ma for four samples from the Linxi Formation. 425-585 Ma, together with the ~500 Ma age for the metamorphism event previously determined for Northeast China, indicates that their provenance is the metamorphic rocks of Pan-African age that have a tectonic affinity to NE China. A few older zircons with U-Pb ages at 1689-1801 Ma, 1307 1414 Ma, 593-978 Ma are also present, revealing the Neoproterozoic history of NE China. The youngest population shows a peak at ca. 252 Ma, suggesting that the main deposition of the Linxi Formation was at late Permain. Moreover, the ca. 250 Ma zircon grains of all four samples yield weighted mean ^206pb/^238U ages of 250 ± 3 Ma, 248 ± 3 Ma, 249 ± 3 Ma, and 250 ± 2 Ma, respectively. These ages, together with the youngest zircon age in the sample ZJB-28 （ca. 238 Ma）, suggest that the deposition of the Linxi Formation extended to the early Triassic. Combining with previous results, we suggest that the final collision of the Central Asian Orogenic Belt （CAOB） in the southern of Linxi Formation, which located in the Solonker-Xra Moron-Changchun suture, and the timing for final collision should be at early Triassic.

Late syn-to post-collisional magmatism in Madagascar:The genesis of the Ambalavao and Maevarano Suites

The East African Orogen involves a collage of Proterozoic microcontinents and arc terranes that became wedged between older cratonic blocks during the assembly of Gondwana.The Ediacaran-Cambrian Ambalavao and Maevarano Suites in Madagascar were emplaced during the waning orogenic stages and consist of weakly deformed to undeformed plutonic rocks and dykes of mainly porphyritic granite but also gabbro,diorite and charnockite.U-Pb geochronological data date emplacement of the Ambalavao Suite to between ca.580 Ma and 540 Ma and the Maevarano Suite to between ca.537 Ma and522 Ma.Major and trace element concentrations are consistent with emplacement in a syn-to postcollisional tectonic setting as A-type(anorogenic) suites.Oxygen(δ^(18)O of 5.27‰-7.45‰) and hafnium(ε(Hf)(t) of-27.8 to-12.3) isotopic data from plutons in the Itremo and Antananarivo Domains are consistent with incorporation of an ancient crustal source.More primitive δ^(18)O(5.27‰-5.32‰) andε(Hf)(t)(+0.0 to+0.2) isotopic values recorded in samples collected from the Ikalamavony Domain demonstrate the isotopic variation of basement sources present in the Malagasy crust.The Hf isotopic composition of Malagasy zircon are unlike more juvenile Ediacaran-Cambrian zircon sou rces elsewhere in the East African Orogen and,as such,Madagascar represents a distinct and identifiable detrital zircon source region in Phanerozoic sedimentary provenance studies.Taken together,these data indicate that high-T crustal anatexis,crustal assimilation and interaction of crustal material with mantle-derived melts were the processes operating during magma emplacement.This magmatism was coeval with polyphase deformation throughout Madagascar during the amalgamation of Gondwana and magmatism is interpreted to reflect lithospheric delamination of an extensive orogenic plateau.

胶辽吉造山带碰撞后岩浆作用:来自辽东-吉南地区巨斑状和球粒状花岗岩的约束

胶辽吉造山带辽东-吉南地区卧龙泉、双岔、八河川等巨斑状花岗岩体形成于造山峰期之后,记录了造山带演化的重要信息,对于探讨整个胶辽吉造山带构造演化具有重要意义。通过对巨斑状花岗岩研究,识别出局部侵入其中的球粒状花岗岩,并对采集自造山带东部和西部典型岩体的3件巨斑状花岗岩和1件球粒状花岗岩开展了岩相学、锆石U-Pb年代学、Lu-Hf同位素及主微量元素研究。结果显示巨斑状花岗岩具有硅含量相对较低、全碱较高、A/CNK值变化较大(0.86~1.19)等特征。虽然双岔巨斑状花岗岩中见有石榴子石,但全岩地球化学特征表现出准铝质、锆饱和温度较高等A型花岗岩特征;宝甸地区花岗岩中也有石榴子石,显示了S型花岗岩地球化学特征。卧龙泉和双岔巨斑状花岗岩体侵位时代为1880~1895Ma,球粒状花岗岩形成于1870±13Ma,宝甸地区巨斑状含石榴花岗岩侵位于1845±13Ma左右;来自这些锆石的原位εHf(t)值介于-3.6~+4.2之间,相应的二阶段模式年龄为2474~2730Ma。本研究认为,辽吉造山带碰撞后花岗质岩石成因较为复杂:球粒状花岗岩反映了岩浆过冷度较大、快速侵位至浅表过程;宝甸地区巨斑状花岗岩具有S型花岗岩特征;具有A型花岗岩特征的巨斑状花岗岩则反映了深部物质和加厚地壳均有贡献。结合前期报道的同时代碰撞后I型和A型花岗岩以及变质岩的研究等,本文认为辽东半岛巨斑状和球粒状花岗岩的产出与胶辽吉造山带碰撞后强烈的下地壳作用有关,反映了造山带去根垮塌、岩石圈伸展过程,代表了碰撞后花岗质岩浆作用。

吉林红旗岭晚三叠世镁铁超镁铁质侵入体矿物化学和岩石地球化学特征:对镍铜成矿的启示

吉林红旗岭镁铁超镁铁质侵入岩群位于中亚造山带东段南缘,由3个北西向岩带(I、II、III)组成,包括30多个小岩株,其中I-岩带的部分岩体伴有铜镍矿化,并且其1和7号岩体分别形成了中型和大型岩浆铜镍硫化物型矿床。矿床主要容矿岩石为辉橄岩、橄辉岩、斜方辉石岩、二辉石岩、苏长岩和辉长岩。主量元素方面,红旗岭岩群具有富镁(w(MgO)=20.7%~31.1%)、低钛(w(TiO_(2))=0.33%~0.79%)、低碱(w(K 2 O+Na 2 O)=0.60%~2.29%)和硅(w(SiO_(2))=40.0%~53.0%)变化范围大的特征;微量元素方面,红旗岭岩群呈现弱富集LREE和LILE(Th)以及亏损HREE和HFSE(Nb-Ta-Ti)。岩相学、地球化学和矿物(橄榄石、斜方辉石、单斜辉石、尖晶石、斜长石和角闪石)主微量元素特征表明,红旗岭岩群明显不同于洋岛型玄武岩、阿拉斯加型环状杂岩和科马提岩,但与岛弧玄武岩以及中亚造山带西段的“黄山西”和“黄山东”铜镍硫化物矿床的容矿超镁铁质岩相似,其母岩浆是一种富Mg、亏损Nb-Ta的岛弧拉斑玄武质熔体,形成于晚三叠世古亚洲洋闭合后伸展环境,演化过程中经历了地壳混染和分离结晶作用,含矿母岩浆可能经历了硫化物的“二次熔离”,最终形成了铂族元素(PGE)亏损型岩浆铜镍硫化物矿床。

藏南亚东地区中新世岩浆活动及构造意义

喜马拉雅淡色花岗岩是研究造山带构造-岩浆演化历史的岩石探针。亚东淡色花岗岩位于高喜马拉雅序列中部,其成因机制和构造意义有待进一步的研究和讨论。本研究提供了新的亚东地区淡色花岗岩和花岗片麻岩的全岩地球化学和锆石年代学数据。亚东淡色花岗岩具有相对较高的SiO_(2)、K_(2)O含量,和相对较低的CaO、FeO^(T)、MgO含量,属于过铝-强过铝质、高钾钙碱性花岗岩。它们具有较低的稀土含量,相对富集的LREE含量,明显的Eu负异常。这些地球化学特征同典型的高喜马拉雅淡色花岗岩极为一致。本研究获得了顶噶二云母花岗岩约23Ma和21Ma的两期结晶年龄,并且认为该地区高喜马拉雅结晶岩系的部分熔融可能早在36~30Ma就已经开始了。获得亚东淡色花岗岩的ε_(Nd)(t)值和(^(87)Sr/^(86)Sr)i分别为-16.7~-13.8和0.754080~0.791009,与亚东变沉积岩的Sr-Nd同位素组成极其一致,而花岗片麻岩具有明显更高的ε_(Nd)(t)值和(^(87)Sr/^(86)Sr)i,分别为-9.0~-8.8和0.847193~0.866306。因此,我们认为亚东淡色花岗岩源自高喜马拉雅结晶岩系中变沉积岩的部分熔融,且不含或极少有花岗片麻岩的物质贡献。综合全岩地球化学、变质岩石学及年代学研究,我们认为高喜马拉雅结晶岩系在埋藏加厚的过程中就已经发生了白云母为主的脱水部分熔融,在随后的伸展构造阶段发生大规模减压熔融,产生大量中新世淡色花岗岩。

显生宙碰撞造山带超高温变质作用的加热机制:来自二维数值模拟的约束

大量的岩石学证据表明:碰撞造山带中常发育900~1100℃的超高温变质作用。然而,碰撞造山带中如何出现如此极端的超高温条件仍然存在争议。为了更好地理解超高温变质作用加热机制和碰撞造山带中主要热源的相对贡献,我们建立了一系列高分辨率二维热-动力学模型,借此探讨了俯冲大陆岩石圈密度亏损程度、大陆地壳放射性生热率和大陆汇聚速率等因素对碰撞造山过程中超高温变质主要热源的影响。当大陆岩石圈密度亏损(Δρ=ρ软流圈地幔-ρ岩石圈地幔)大于50kg/m^(3)时,有利于发生大陆平板俯冲,软流圈地幔无法上涌为地壳物质提供热源;此时,具有较高放射性生热率(>3μW/m^(3))的地壳可以发生“浅俯冲-折返”型超高温变质作用。而当大陆岩石圈密度亏损小于10kg/m^(3)时,大陆上地壳在深俯冲阶段首先发生超高压榴辉岩相变质作用,随后伴随着大陆岩石圈地幔后撤和软流圈上涌,进而出现以异常高的地幔热流加热为主的“深俯冲-折返”型超高温变质作用。此外,较低的大陆汇聚速率(<1cm/yr)更有利于“深俯冲-折返”型超高温变质作用的产生。将数值模拟结果与特提斯构造域的变质岩石数据和地球物理观测进行对比,我们认为在现今板块构造体制下,由具有密度亏损程度较高的大陆岩石圈平俯冲有利于“浅俯冲-折返”型超高温变质作用的发生,而由密度亏损程度较低的大陆岩石圈俯冲可能导致“深俯冲-折返”型超高温变质作用的产生。

东昆仑百吨沟花岗岩岩石地球化学、锆石U-Pb年龄与Hf同位素特征及其构造意义

东昆仑造山带志留纪-泥盆纪的演化存在着争议,A型花岗岩常用来限定造山过程中构造转换的时间。百吨沟花岗岩岩体位于东昆仑造山带东段的五龙沟金矿集区,目前缺乏系统的研究,本文对其进行了岩石地球化学、锆石U-Pb年代学及Hf同位素研究。锆石U-Pb定年表明,该岩体结晶年龄为417.9±3.5 Ma。岩石地球化学分析结果显示,岩石高硅(SiO_(2)=71.2%~77.2%)、富碱(K_(2)O+Na_(2)O=8.23%~10.70%)、低MgO(0.04%~0.22%)和CaO(0.09%~0.95%),具有富集大离子亲石元素(Rb、K、Th、U)、亏损高场强元素(P、Ti)的特征,具有明显的负铕异常和"海鸥型"稀土元素配分模式,并且岩石具有较高的Ga/Al、TFeO/MgO值以及Zr饱和温度,表明该岩体为A型花岗岩。此外,锆石的εHf(t)=-0.6~1.9,对应的二阶段模式年龄t2DM介于1442~1284 Ma之间,推测该A型花岗岩主要源自早期具有相似Hf同位素的长英质火成岩部分熔融。该花岗岩具有A2型花岗岩的特征,指示其形成于后碰撞伸展环境。东昆仑造山带发育大量近同时的A2型花岗岩,反映其在晚志留世时进入后碰撞伸展阶段。

桐柏-大别碰撞造山带的基本组成与结构

桐柏 -大别碰撞造山带的组成与结构 ,主要是印支期碰撞及高压、超高压变质期后伸展构造和中新生代热 -构造演化的结果 .在组成上 ,除了燕山期及其后的岩浆活动和盆地堆积产物以外 ,主要包括核部杂岩单元、超高压单元、高压单元、绿帘 -蓝片岩单元和沉积盖层单元等 ,此外还有一些镁铁质和超镁铁质岩体残留或侵入其中 .桐柏 -大别碰撞造山带的整体结构样式类似于北美西部的变质核杂岩带 ,即以总体具穹隆形态及多层拆离滑脱带的发育为特征 ,构成了以罗田和桐柏山为核部的两个穹隆 .超高压单元、高压单元和绿帘蓝片岩单元作为不同的岩片夹持于核部杂岩和沉积盖层之间 ,其分布格局受碰撞期后伸展构造格架所制约 .

西藏冈底斯中新世斑岩铜矿带:埃达克质斑岩成因与构造控制

作为贱金属主要来源的斑岩铜矿床,大多数产出于大陆边缘和岛弧环境。普遍认为。被俯冲洋壳板片释放流体交代的地幔楔部分熔融形成的玄武质岩浆,在相对封闭系统结晶分异和/或同化混染形成含铜长英质岩浆。然而.我们的研究表明,在西藏碰撞造山带,发育一条具有巨大成矿潜力的中新世斑岩铜矿带,含铜斑岩具有埃达克岩地球化学特性,来源于被加厚的藏南镁铁质下地壳,但俯冲的新特提斯洋壳板片部分熔融也不能完全被排除。斑岩铜矿形成于陆-陆后碰撞伸展时期(13～18 Ma),即青藏高原迅速抬升之后。横切碰撞造山带的南北向正断层系统,类似于岛弧环境下的横切弧的断层系统,成为埃达克质斑岩岩浆快速上升和就位的通道与场所,并使岩浆热液系统中大量的含矿流体充分地分离而成矿。

大别山区(安徽部分)的构造格局和演化过程

大别山区是扬子和中朝大陆板块之间的碰撞造山带,由扬子大陆板块中的前陆褶冲带、俯冲盖层和俯冲基底、包含在俯冲基底中的含柯石英和金刚石的超高压变质帝、变质蛇绿混杂岩带、中朝大陆板块南缘的弧前复理石推覆体以及其北缘的反向褶冲带、北部边缘为磨拉斯的后继盆地组成。古大别海洋板块于早古生代向北俯冲时,中朝大陆板块南缘可能出现过火山弧和弧后盆地。卷入前陆褶冲带的地层以及榴辉岩的Sm/Nd同位素定时表明,两个大陆板块的强烈碰撞发生在中生代早期。

柴达木盆地北缘早古生代碰撞造山系统

柴达木盆地北缘在早古生代形成了一条碰撞造山带,该造山带结构保存较完整,可分辨出深俯冲板片、火山岛弧带、蛇绿杂岩带、岛弧深成岩带等组成单元。其中,俯冲板块主要由中元古代鱼卡河岩群和中新元古代花岗片麻岩构成,在寒武纪末—奥陶纪可能全部或部分俯冲到岩石圈深部,发生了高压—超高压变质作用。火山岛弧主要由中基性火山岩、细碎屑岩等组成,成岩时代为晚寒武世—奥陶纪。蛇绿杂岩带由超镁铁质岩、辉长岩、玄武岩和少量硅质岩组成,形成于弧后扩张脊构造背景,成岩时代为寒武纪—奥陶纪。岛弧深成岩成分变化较大,由闪长岩变化到花岗岩,成岩时代为奥陶纪。而造山带北侧的欧龙布鲁克微陆块则具有双层结构,由德令哈杂岩和达肯大坂岩群构成基底,盖层为全吉群。

阿尔金碰撞造山带西段的构造特征

根据阿尔金山西段前早古生代变质岩的岩石组成、沉积建造、变形变质作用改造历史、岩石地球化学特征等研究,将阿尔金碰撞造山带西段划分为3个构造单元:北阿尔金地块、中阿尔金地块(包括英格里克构造-蛇绿混杂岩带、肖鲁克·布拉克高压变质岩带和塔什萨依玉石矿高绿片岩相—低角闪岩相变质岩带)和南阿尔金地块(包括南阿尔金中—新元古界隆起带和阿尔金南缘复合构造-蛇绿混杂岩带)。提出该碰撞造山带经历了前长城纪古陆核形成阶段、长城纪—青白口纪不同基底联合阶段和早古生代洋陆转换阶段3个阶段的构造演化。

中国中西部中、新生代前陆盆地与挤压造山带耦合分析

中国中西部主要由中、新生代造山带与中、新生代盆地构成盆山格局 :秦岭造山带与南北两侧四川盆地与鄂尔多斯盆地 ;天山造山带与南北两侧塔里木盆地与准噶尔盆地 ;哀牢山造山带与东西两侧楚雄盆地与兰坪思茅盆地等 ,总体上构成盆山耦合。根据挤压造山带类型与前陆盆地类型 ,可以划分出 3种耦合类型 ,即 ( 1)碰撞造山带与周缘前陆盆地 ,( 2 )俯冲造山带与弧后前陆盆地及 ( 3)再生造山带与再生前陆盆地。因此前陆盆地是伴随着造山带的形成与演化而发育 ,造山带断滑系统直接控制前陆盆地结构、沉积层序及构造样式等 。