秦岭岩群中斜长角闪岩的年代学、地球化学特征及其地质意义     

柏治安 《地质与勘探》2020,56(2):372-386

本文对秦岭岩群中的三个斜长角闪岩（变质沉积岩）样品进行了岩石学、锆石U-Pb年代学和岩石地球化学研究,限定了秦岭岩群的形成时代,讨论了秦岭岩群的构造背景及归属问题。锆石定年结果显示了971 Ma、1222 Ma和840 Ma三个最大沉积年龄。秦岭岩群是一个杂岩体,秦岭岩群中至少存在中元古代（较老组成部分）和新元古代早期（较新组成部分）的岩性单元。秦岭岩群变质沉积岩的锆石年龄峰主要集中在中元古代-新元古代早期,具有与扬子块体和华北块体明显不同的锆石年代学特征,秦岭岩群在中元古代-新元古代早期为独立发展的微陆块。结合秦岭岩群的年代学特征及前人的研究结果,秦岭岩群中的变质沉积岩应沉积于弧相关的构造环境。  相似文献   

内蒙古甲乌拉铅锌银矿绢云母~(40)Ar-~(39)Ar年龄及其地质意义     

牛斯达 《地质与勘探》2020,56(1):59-67

内蒙古甲乌拉大型铅锌银矿位于大兴安岭成矿带北段,为一与火山-次火山作用有关的浅成低温热液型矿床。该矿床绢云母的矿物学特征方面研究程度较低,绢云母的年龄还未见报道。本次研究拟从绢云母入手,利用电子探针和~(40)Ar/~(39)Ar同位素年龄测定,研究其矿物学特征,测定其年龄,进一步探究该矿区热液事件的发生和地球动力学背景,增进对该矿床成矿机制的理解。甲乌拉矿床绢云母~(40)Ar/~(39)Ar坪年龄为133. 27±0. 66 Ma,等时线年龄为131. 88±0. 83 Ma。研究认为,甲乌拉矿床绢云母可能代表了发生于矿化后的另外一期热液事件。该热液事件发生于古太平洋板块俯冲方向改变之后,可能与碰撞后的伸展背景有关。  相似文献   

东海晚中生代岩浆弧与陆缘汇聚作用：碎屑锆石U- Pb年代约束   总被引：2，自引：0，他引：2  

李晓龙  许长海  高顺莉  黄湘通  赵洪  张成晨 《地质学报》2020,94(2):480-490

晚中生代是古太平洋板块俯冲东亚大陆的重要时期,也是华南大陆构造-岩浆活动的重要时期。本文通过东海陆架盆地紧邻海礁隆起ECSs611钻井的渐新统花港组(1626～1638m)砂岩和白垩系(1638～1689m)砂岩碎屑锆石U-Pb同位素和微量元素等研究,获得了～163Ma和～120Ma两期岩浆-变质事件的锆石U-Pb年龄记录。两期岩浆锆石均具有结晶温度低(556～732℃)、流体活动元素U富集(含量82×10~(-6)～3412×10~(-6))及高场强元素Nb亏损(含量0.6×10~(-6)～13.8×10~(-6))等特点,它们形成于岩浆弧构造环境。与洋壳锆石相比,两期岩浆锆石元素Y含量(371×10~(-6)～2700×10~(-6))和U/Yb比值(0.2～6.7)偏低,指示其属于大陆锆石类型。其它碎屑锆石年龄(如2.5～2.4Ga,1.7～1.6Ga,320 Ma和256～207 Ma)与华南大陆主要构造事件一致,初步认为东海海礁隆起应属于华南大陆(华夏地块)东延的部分。如果将海礁-虎皮礁隆起作为晚侏罗世至早白垩世岩浆弧一部分,与东海福州凹陷弧前盆地和西南日本至台湾俯冲增生杂岩等单元联结起来,区域上可构成受古太平洋板块俯冲控制的晚中生代东亚大陆边缘构造轮廓,即岩浆弧→弧前盆地→俯冲增生杂岩。  相似文献   

湘东北金鸡金矿床岩体成岩机制     

隗含涛  邵拥军  汪程  刘清泉  刘忠法  肖克炎 《地球学报》2020,41(2):253-266

江南造山带湖南段中早古生代花岗质岩石对于研究早古生代构造演化以及金成矿作用具有重要的意义。位于该区中段的金鸡金矿床钻孔中新发现有两类花岗质岩石,分别为花岗岩和花岗闪长岩。对两类岩体样品进行了锆石LA-ICP-MS U-Pb测年,获得的年龄分别为(425.2±1.5)Ma和(430.6±1.5)Ma。岩石地球化学数据表明,花岗岩属I型花岗岩,其来源于地壳中变泥质岩石的部分融熔;花岗闪长岩属埃达克岩,其起源于地壳中变砂质岩石的部分融熔。Sr-Nd同位素分析显示,金鸡花岗闪长岩具有较高的(87Sr/86Sr)i(0.722369~0.722488)、较低的(143Nd/144Nd)i(0.511941~0.511990)以及εNd(t)值较低(–8.2~–7.2),并且金鸡花岗闪长岩的二阶段Nd模式年龄值为1.75~1.84 Ga,与江南造山带变质基底的二阶段模式年龄(1.65~2.14 Ga)一致。金鸡金矿床花岗岩和花岗闪长岩的岩石地球化学、年代学以及Sr-Nd同位素特征表明二者是华南早古生代陆内造山事件的产物,岩体成因及地球动力学背景的研究将有助于揭示湘东北地区金矿形成的地球动力学机制。  相似文献   

Granitoid rocks of Naxos,Greece: regional geology and petrology     

GEORGIA PE-PIPER  C. N. KOTOPOULI  DAVID J. W. PIPER 《Geological Journal》1997,32(2):153-171

Granitic gneiss in a Miocene extensional core complex on Naxos locally preserves primary igneous textures. On an outcrop scale, these include mafic enclaves; in thin section, feldspar phenocrysts contain unoriented accessory mineral inclusions. The gneiss is interpreted as having a Hercynian granite protolith. Contrary to previous accounts, migmatites are rare in the gneiss. The granite is geochemically similar to post-collisional extension-related granites and differs from the predominant granodiorites found in the Hercynian basement of northwestern Greece. An I-type hornblende–biotite granite pluton was emplaced during Miocene extension in western Naxos. It is a typical subduction-related pluton emplaced under conditions of back-arc extension. The pluton is cut by later leucogranite that geochemically resembles the granite dykes that cut the migmatites. In northern Naxos, minor leucogranite intrusions are of two geochemical types. One is everywhere deformed and geochemically resembles the leucogranite that cuts the Western pluton. The other is variably deformed and new geochronology shows that it has an age of 10 Ma. © 1997 John Wiley & Sons, Ltd.  相似文献   

Delineation of an exhumed intermediate-depth crustal fault in a collisional setting: An example from the Himalaya     

Dyuti Prakash Sarkar  Jun-ichi Ando  Kaushik Das  Gautam Ghosh 《Island Arc》2024,33(1):e12515

The regionally prominent main boundary thrust (MBT) of the Himalayan fold-thrust belt in northwest India is typically defined by the presence of Proterozoic rocks in the hanging wall and Cenozoic rocks in the footwall. The present study focuses on identifying the MBT contact across Gambar River section in Himachal Pradesh, India, using alternative methodologies, such as the meter-scale litho-structural mapping, followed by detrital zircon U–Pb geochronology to precisely identify the thrust contact and provide insights on the deformation history of the MBT zone. We have identified a sharp change in the age (from ~600 to ~61 Ma) of the sedimentary units along a narrow zone in the study area by detrital zircon U–Pb geochronology using LA-ICP-MS. The sharp change in the detrital zircon U–Pb age data thus delineate the MBT occurring in the area along a < ~1 m thickness. The lithological assemblage and the age data indicate the unified maximum depositional age from ~700 to ~600 Ma for the hanging wall rocks, which have been equated with the Krol Group of the Lesser Himalayan Sequence (LHS). In comparison, the footwall rocks exhibit the maximum depositional age of ~61 Ma and have been equated with the Cenozoic Subathu Formation of the Sub-Himalayan Sequence (SHS).  相似文献   

柴达木盆地北缘西段下石炭统物源和构造背景：来自碎屑岩U- Pb年代学与地球化学的约束     

胡俊杰  施辉  马立成  马寅生  王嘉琦  钟畅 《地质学报》2024,98(4):1056-1067

为查明柴达木盆地北缘西段早石炭世沉积物来源和构造背景,本次研究采集小赛什腾山怀头他拉组沉积岩进行碎屑岩锆石U- Pb年代学和全岩微量元素地球化学分析。研究表明：测试样品微量元素蛛网图呈平坦型,富Th、U、Hf,贫Co、Sc、Ni、V元素;砂岩轻重稀土元素分馏明显,属轻稀土富集型,具有中等负Eu异常;Cr/Zr、Sm/Nd、Th/Sc及Th/U等微量元素比值和判别图版显示研究区怀头他拉组为上地壳长英质物源区。沉积岩微量元素、稀土元素含量及特征比值显示,研究区样品与大陆弧环境砂岩具有极为相似的地球化学特征,相关构造环境投图同样表明怀头他拉组沉积环境以大陆弧为主,兼有主动大陆边缘特征。怀头他拉组碎屑锆石U- Pb年龄可划分出3个年龄区间,480～402 Ma,1493～900 Ma和1908～1803 Ma。年龄谱呈早古生代单峰值特征,峰值年龄为414 Ma,反映物源区与柴北缘加里东期构造带内早古生代晚期的岩浆作用关系密切。结合前人区域上古地理、古水流证据,综合分析认为小赛什腾山下石炭统怀头他拉组物源主要来自于柴北缘高压—超高压变质带。  相似文献   

Modification of the Sm–Nd isotopic system in garnet induced by retrogressive fluids          下载免费PDF全文

Shi‐Chao An  Shu‐Guang Li  Zhen Liu 《Journal of Metamorphic Geology》2018,36(8):1039-1048

Garnet, as a major constitutive mineral of eclogite, is important for Sm–Nd dating of eclogite due to its high Sm/Nd ratio and its stability during retrogression. However, a comprehensive study of the petrography, mineral chemistry, garnet water content, and Sm–Nd isotopic composition of eclogites from the Bixiling massif, Central Dabie Zone (CDZ), reveals significant modification of the Sm–Nd isotopic system in garnet as a result of retrogression. This problem constitutes a challenge for Sm–Nd dating of the Bixiling eclogites, with the Sm–Nd isochron ages of 218 ± 4 to 210 ± 9 Ma reported in the literature being younger than 226 ± 3 Ma, which is the generally accepted peak metamorphic age of the CDZ. Petrographic analysis reveals heterogeneity in colour within single fractured garnet grains. There are light‐pink garnet (Grt‐P) and red garnet (Grt‐R) types that possess distinct chemical compositions. Compared to Grt‐P, Grt‐R has higher Fe and andradrite contents but lower Al and grossular contents. Grt‐P also has lower water contents (15–35 ppm) than Grt‐R (34–65 ppm), which, together with the spatial association between Grt‐R and fractures, suggests that the colour change is related to fluid alteration. Grt‐P is an ultra‐high‐pressure (UHP) mineral, and Grt‐R is the product of the interaction between Grt‐P and a fluid during retrogression. Moreover, Grt‐R features lower Sm and Nd contents but higher Sm/Nd ratios than Grt‐P. The Sm–Nd isochrons defined by UHP minerals (Grt‐P+Omp+Rt or Grt‐P+Cpx+WR) from three eclogite samples yield consistent ages of 226.0 ± 3.8 Ma, 225.0 ± 3.9 Ma and 226.2 ± 6.9 Ma, which are identical to the peak metamorphic age of 226 ± 3 Ma for the CDZ. The retrogressed garnet (i.e., Grt‐R), omphacite and rutile, together define a pseudoisochron with younger ages of 218.9 ± 5.9 to 202.8 ± 4.8 Ma, which are geologically meaningless. The increase in the Sm/Nd ratio with constant or lower ¹⁴³Nd/¹⁴⁴Nd ratios during the transformation of Grt‐P to Grt‐R was probably the cause of these younger ages.  相似文献   

The geological evolution of the Gangpur Schist Belt,eastern India: Constraints on the formation of the Greater Indian Landmass in the Proterozoic     

Tuhin Chakraborty  Dewashish Upadhyay  Sameer Ranjan  Kamal L. Pruseth  Jayanta K. Nanda 《Journal of Metamorphic Geology》2019,37(1):113-151

The Central Indian Tectonic Zone (CITZ) is a Proterozoic suture along which the Northern and Southern Indian Blocks are inferred to have amalgamated forming the Greater Indian Landmass. In this study, we use the metamorphic and geochronological evolution of the Gangpur Schist Belt (GSB) and neighbouring crustal units to constrain crustal accretion processes associated with the amalgamation of the Northern and Southern Indian Blocks. The GSB sandwiched between the Bonai Granite pluton of the Singhbhum craton and granite gneisses of the Chhotanagpur Gneiss Complex (CGC) links the CITZ and the North Singhbhum Mobile Belt. New zircon age data constrain the emplacement of the Bonai Granite at 3,370 ± 10 Ma, while the magmatic protoliths of the Chhotanagpur gneisses were emplaced at c. 1.65 Ga. The sediments in the southern part of the Gangpur basin were derived from the Singhbhum craton, whereas those in the northern part were derived dominantly from the CGC. Sedimentation is estimated to have taken place between c. 1.65 and c. 1.45 Ga. The Upper Bonai/Darjing Group rocks of the basin underwent major metamorphic episodes at c. 1.56 and c. 1.45 Ga, while the Gangpur Group of rocks were metamorphosed at c. 1.45 and c. 0.97 Ga. Based on thermobarometric studies and zircon–monazite geochronology, we infer that the geological history of the GSB is similar to that of the North Singhbhum Mobile Belt with the Upper Bonai/Darjing and the Gangpur Groups being the westward extensions of the southern and northern domains of the North Singhbhum Mobile Belt respectively. We propose a three‐stage model of crustal accretion across the Singhbhum craton—GSB/North Singhbhum Mobile Belt—CGC contact. The magmatic protoliths of the Chhotanagpur Gneisses were emplaced at c. 1.65 Ga in an arc setting. The earliest accretion event at c. 1.56 Ga involved northward subduction and amalgamation of the Upper Bonai Group with the Singhbhum craton followed by accretion of the Gangpur Group with the Singhbhum craton–Upper Bonai Group composite at c. 1.45 Ga. Finally, continent–continent collision at c. 0.96 Ga led to the accretion of the CGC with the Singhbhum craton–Upper Bonai Group–Gangpur Group crustal units, synchronous with emplacement of pegmatitic granites. The geological events recorded in the GSB and other units of the CITZ only partially overlap with those in the Trans North China Orogen and the Capricorn Orogen of Western Australia, indicating that these suture zones are not correlatable.  相似文献   

Integrated garnet and zircon–titanite geochronology constrains the evolution of ultra‐high–pressure terranes: An example from the Sulu orogen     

Da Wang  Jeffrey D. Vervoort  Christopher M. Fisher  Hui Cao  Guangxu Li 《Journal of Metamorphic Geology》2019,37(5):611-631

Dating ultra‐high–pressure (UHP) metamorphic rocks provides important timing constraints on deep subduction zone processes. Eclogites, deeply subducted rocks now exposed at the surface, undergo a wide range of metamorphic conditions (i.e. deep subduction and exhumation) and their mineralogy can preserve a detailed record of chronologic information of these dynamic processes. Here, we present an approach that integrates multiple radiogenic isotope systems in the same sample to provide a more complete timeline for the subduction–collision–exhumation processes, based on eclogites from the Dabie–Sulu orogenic belt in eastern China, one of the largest UHP terranes on Earth. In this study, we integrate garnet Lu–Hf and Sm–Nd ages with zircon and titanite U–Pb ages for three eclogite samples from the Sulu UHP terrane. We combine this age information with Zr‐in‐rutile temperature estimates, and relate these multiple chronometers to different P–T conditions. Two types of rutile, one present as inclusions in garnet and the other in the matrix, record the temperatures of UHP conditions and a hotter stage, subsequent to the peak pressure (‘hot exhumation') respectively. Garnet Lu–Hf ages (c. 238–235 Ma) record the initial prograde growth of garnet, while coupled Sm–Nd ages (c. 219–213 Ma) reflect cooling following hot exhumation. The maximum duration of UHP conditions is constrained by the age difference of these two systems in garnet (c. 235–220 Ma). Complementary zircon and titanite U–Pb ages of c. 235–230 Ma and c. 216–206 Ma provide further constraints on the timing of prograde metamorphism and the ‘cold exhumation' respectively. We demonstrate that timing of various metamorphic stages can thus be determined by employing complementary chronometers from the same samples. These age results, combined with published data from adjacent areas, show lateral diachroneity in the Dabie–Sulu orogeny. Three sub‐blocks are thus defined by progressively younger garnet ages: western Dabie (243–238 Ma), eastern Dabie–northern Sulu (238–235 Ma) and southern Sulu terranes (225–220 Ma), which possibly correlate to different crustal slices in the recently proposed subduction channel model. These observed lateral chronologic variations in a large UHP terrane can possibly be extended to other suture zones.  相似文献