新疆额尔宾山花岗岩侵位年龄和成因及其对南天山洋闭合时代的限定

额尔宾山花岗岩岩体位于南天山晚古生代侵入岩带,对该花岗岩进行锆石U-Pb定年获得296.1±1.8Ma的年龄,为早二叠世。岩石主量元素分析结果表明,该花岗岩的Si O2含量为66.96%~67.3%,富碱(Na2O+K2O=7.53%~7.97%),K2O/Na2O1(1.15~1.27),属高钾钙碱性系列岩石;Al2O3为15.56%~15.62%,Al2O3K2O+Na2O+Ca O,属于过铝型。岩石稀土元素配分模式呈现轻稀土元素(LREE)富集((La/Yb)N=27.03~30.62)、重稀土元素(HREE)亏损((LREE/HREE)=18.2~20.1)、具有中等程度的负Eu异常(δEu=0.64~0.68)。微量元素判别结果显示,其具有I-A型花岗岩过渡的特征。结合区域地质背景综合分析,初步认定该岩体可能形成于南天山同碰撞向后碰撞构造体制转换时期,据此可以推测南天山洋盆闭合时限至少应该在早二叠世以前。     

全球早古生代造山带(Ⅱ):俯冲-增生型造山

全球早古生代增生造山带极其发育,主要分布在古亚洲洋南北两侧、Iaeptus洋南侧、Rheic洋北侧和环冈瓦纳大陆地带,其中原特提斯洋封闭的产物主要发育在中国境内,大量微陆块在早古生代可能都是冈瓦纳北缘的俯冲-增生带中的重要组成。增生造山带中组成复杂,具有沟-弧-盆体系、海山、洋壳等残存记录,尤以榴辉岩发育为特征,增生造山成为早古生代古亚洲洋和特提斯洋构造体系的显著独特特征。早古生代末中亚早古生代造山带多为微陆块增生造山阶段,沟-弧-盆体系发育,具有增生-软碰撞造山的特点,发生时限较晚,为早古生代末;原特提斯洋中的西昆仑、东昆仑、柴达木北缘、南阿尔金、北阿尔金与北祁连、北秦岭等围限或夹杂的微陆块在早古生代具有相同的增生造山过程,整体是向南俯冲线性增生到冈瓦纳大陆北缘,现今多次重复是早古生代弯山构造所致。400 Ma左右,南部古特提斯洋和北部勉略带的打开,导致其北漂,经复杂变形改造,它们现今为一巨型弯山构造横亘在中国中部,对中国构造格局影响最为重要。     

Distribution of calcareous nannoplankton in surface sediments along the northern KwaZulu-Natal Bight,South Africa

The coccolith assemblages from seafloor sediments over the inner shelf in the northern region of the KwaZulu- Natal Bight on the east coast of South Africa were identified and their distribution determined. In all, 29 Recent species and taxonomic groups, as well as 29 reworked species were recorded. The distribution of the Recent species appears to be governed by environmental features that have been documented in other studies: temperature, salinity, nutrient concentration and water circulation pattern, which reveals the long-term existence of a circulation cell in the sector between Durban Bay and the Thukela River. The outer edge of the cell consists of nutrient-enriched mixed layers and is characterised by an enhanced abundance of Gephyrocapsa oceanica, whereas the central region consists of a stratified nutrient-depleted water mass with elevated abundance of Umbilicosphaera sibogae, Florisphaera profunda, and a group of umbelliform species. The elevated levels of G. oceanica, coupled with the rarity of U. sibogae, F. profunda and the umbelliform species, confirm the presence of a permanent upwelling cell off Richards Bay. The maximum abundance of F. profunda found between Richards Bay and Lake Nhlabane indicates a region of nutrient-depleted (except for nitrite) conditions.     

大兴安岭北段图里河地区满克头鄂博组火山岩年代学及地球化学

对大兴安岭北段图里河地区满克头鄂博组火山岩进行了锆石U-Pb年代学及岩石地球化学研究,以便对其岩石成因和构造背景给予制约。流纹岩LA-ICP-MS锆石U-Pb定年结果表明,该地区满克头鄂博组火山岩形成时代为晚侏罗世(157±1Ma)。该组火山岩具有高硅(Si O2=69.09%~75.92%)、富碱(K2O+Na2O=8.04%~9.23%),贫镁、铁、钙的特征,属高钾钙碱性、偏铝质-弱过铝质岩石;稀土元素配分曲线呈轻稀土富集的右倾形式,(La/Yb)N=5.85~13.53,无铕异常或具有较弱的铕负异常;火山岩样品富集Rb、Th、U、K等大离子亲石元素,亏损Nb、Ta、Ti等高场强元素。Mg#值为12.14~31.01,平均值22,Nb/Ta值(6.67~27.17,平均值12.23),Rb/Sr值(0.35~3.63,平均值1.58),显示火山岩岩浆源区为下地壳。依据岩石地球化学特征、构造判别图解,结合区域构造演化特征,认为满克头鄂博组火山岩形成于蒙古—鄂霍茨克洋闭合的造山后伸展背景。     

华北克拉通北缘东段“开原岩群”的解体及重新认识

根据近年来的同位素年代学资料,对分布于辽北地区的一套构造变质岩系（"开原岩群"或"清河镇岩群"）进行了重新认识和划分,并将其重新定义为清河构造混杂岩,由中太古代、新太古代、中元古代、新元古代、二叠纪等不同时代、不同构造环境的地质体组成.其中,中太古代、新太古代、中元古代岩石来自华北克拉通,而新元古代、二叠纪岩石则来自兴蒙造山带.将原沈家堡子岩组重新划分为新太古代变质表壳岩和中-新太古代变质深成岩,原板石沟岩组（或芦家堡子岩组）厘定为中元古代石门岩组,原照北山岩组重新划分为新元古代南平岩片和晚二叠世照北山岩组,将原佟家屯岩组和尖山子火山岩合并为晚二叠世佟家屯岩组.最后,提出了清河构造混杂岩带为华北克拉通与兴蒙造山带的界线以及古亚洲洋在华北板块北缘东段的最终闭合时间为中三叠世早期（约245Ma）的认识.     

内蒙古巴林右旗晚二叠世埃达克质火山岩特征及其地质意义

内蒙古东南部巴林右旗地区发育晚二叠世埃达克质火山岩,岩石组合为安山岩、粗安岩、英安岩及辉石安山岩,其LA-ICP-MS锆石U-Pb测年结果为256.7±2.7Ma,指示其形成于晚二叠世。地球化学特征显示,该套火山岩属准铝质-弱铝质中钾钙碱性岩石系列,具富Si(SiO_256%)、高Al(Al_2O_315%)、富Na、贫K、高Sr、低Yb和Y等特征,Na_2O/K_2O值为2.33~3.90,Mg~#值为35.3~60.8;稀土元素总量为96.69×10~(-6)~192.4×10~(-6)、轻重稀土元素分馏较明显((La/Yb)_N值为6.27~13.82),具正的Eu(δEu=1~1.67)异常,在原始地幔标准化蛛网图中,富集大离子亲石元素Rb、Ba、U,亏损高场强元素Nb、Ta,为O型(大洋型)埃达克质火山岩地球化学特征。综合区域资料,巴林右旗埃达克质火山岩是残留在地幔中的古亚洲洋残余洋壳部分熔融并受到地幔橄榄岩混染形成的,暗示晚二叠世存在古亚洲洋向华北板块俯冲消亡事件。     

Middle Jurassic–Early Cretaceous tectonic evolution of the Bayanhushuo area,southern Great Xing’an Range,NE China: constraints from zircon U–Pb geochronological and geochemical data of volcanic and subvolcanic rocks

This study presents new zircon U–Pb geochronology, geochemistry, and zircon Hf isotopic data of volcanic and subvolcanic rocks that crop out in the Bayanhushuo area of the southern Great Xing’an Range (GXR) of NE China. These data provide insights into the tectonic evolution of this area during the late Mesozoic and constrain the evolution of the Mongol–Okhotsk Ocean. Combining these new ages with previously published data suggests that the late Mesozoic volcanism occurred in two distinct episodes: Early–Middle Jurassic (176–173 Ma) and Late Jurassic–Early Cretaceous (151–138 Ma). The Early–Middle Jurassic dacite porphyry belongs to high-K calc-alkaline series, showing the features of I-type igneous rock. This unit has zircon ε_Hf(t) values from +4.06 to +11.62 that yield two-stage model ages (T_DM2) from 959 to 481 Ma. The geochemistry of the dacite porphyry is indicative of formation in a volcanic arc tectonic setting, and it is derived from a primary magma generated by the partial melting of juvenile mafic crustal material. The Late Jurassic–Early Cretaceous volcanic rocks belong to high-K calc-alkaline or shoshonite series and have A₂-type affinities. These volcanics have ε_Hf(t) and T_DM2 values from +5.00 to +8.93 and from 879 to 627 Ma, respectively. The geochemistry of these Late Jurassic–Early Cretaceous volcanic rocks is indicative of formation in a post-collisional extensional environment, and they formed from primary magmas generated by the partial melting of juvenile mafic lower crust. The discovery of late Mesozoic volcanic and subvolcanic rocks within the southern GXR indicates that this region was in volcanic arc and extensional tectonic settings during the Early–Middle Jurassic and the Late Jurassic–Early Cretaceous, respectively. This indicates that the Mongol–Okhotsk oceanic plate was undergoing subduction during the Early–Middle Jurassic, and this ocean adjacent to the GXR may have closed by the Late Middle Jurassic–Early Late Jurassic.     

Early Carboniferous ophiolite in central Qiangtang,northern Tibet: record of an oceanic back-arc system in the Palaeo-Tethys Ocean

Zircon U–Pb dating of two samples of metagabbro from the Riwanchaka ophiolite yielded early Carboniferous ages of 354.4 ± 2.3 Ma and 356.7 ± 1.9 Ma. Their positive zircon εHf(t) values (+7.9 to +9.9) indicate that these rocks were derived from a relatively depleted mantle. The metagabbros can be considered as two types: R1 and R2. Both types are tholeiitic, with depletion of high-field-strength elements (HFSE) and enrichment of large-ion lithophile elements (LILE) similar to those of typical back-arc basin basalts (BABB), such as Mariana BABB and East Scotia Ridge BABB. Geochemical and isotopic characteristics indicate that the R1 metagabbro originated from a back-arc basin spreading ridge with addition of slab-derived fluids, whereas the R2 metagabbro was derived from a back-arc basin mantle source, with involvement of melts and fluids from subducted ocean crust. The Riwanchaka ophiolite exhibits both mid-ocean ridge basalts- and arc-like geochemical affinities, consistent with coeval ophiolites from central Qiangtang. Observations indicate that the Qiangtang ophiolites developed during the Late Devonian–early Carboniferous (D₃–C₁) in a back-arc spreading ridge above an intra-oceanic subduction zone. Based on our data and previous studies, we propose that an oceanic back-arc basin system existed in the Longmuco–Shuanghu–Lancang Palaeo-Tethys Ocean during the D₃–C₁ period.     

兴蒙造山带晚古生代伸展减薄过程:来自内蒙林西地区岩体的地球化学证据

内蒙古林西县双井地区出露一套含暗色包体的花岗质岩体,位于双井片岩和房框子单元花岗质片麻岩接触带,该岩体对厘定古亚洲洋演化阶段、西伯利亚板块和阿穆尔板块最终碰撞缝合时限具有重要意义。本文对该岩体进行了详细的岩相学、岩石地球化学以及锆石U-Pb年代学研究,讨论了该岩体成因、岩浆源区以及研究区造山带地壳演化等问题。岩体中暗色包体和周边花岗岩大部分锆石记录了～285Ma和～270Ma两期年龄,少量锆石记录了～320Ma的较老年龄,表明该区域在晚石炭世就存在岩浆活动,并在～285Ma、～270Ma更为显著且岩浆活动具有幕式发生的特点,通过锆石的Ti温度计算得岩浆形成温度为～670℃。暗色包体相较周边花岗岩部分更富Al_2O_3(13.96%)、CaO(1.61%)、Na_2O(4.61%)以及Fe_2O_3(3.67%)、MgO(0.62%)、TiO_2(0.28%)、P_2O_5(0.08%)等,但贫K_2O(2.10%),但二者发育有一致的变形现象,具有相同的侵位时代(误差范围内一致)、相似的微量元素配分模式、相近的Sr-Nd-Hf同位素组成指示二者可能为同源岩浆不同演化阶段的产物。此外,暗色包体样品中,Zr/Hf比值介于31.74～37.08之间(接近原始地幔的Zr/Hf比值36.25),黑云母有壳源和壳幔混合源两种成因类型,I_(Sr)值介于0.7039-0.7055之间,ε_(Nd)(t)值介于-7.30～-5.87之间,锆石的ε_(Hf)(t)介于-3.58～6.72之间等地球化学特征均指示暗色包体的母岩浆在形成过程中有幔源物质的加入,以上特征显示岩体为壳幔混合源岩浆经历不同演化阶段后的产物。岩体中锆石Eu/Eu~*与地壳厚度的拟合结果显示研究区在 ca.290～270Ma 地壳经历了一次显著的减薄过程(ca.50～35km),为区域存在地幔物质上涌提供了动力学证据。结合前人资料,本次研究的含暗色包体的花岗质岩体属于大石寨期,其母岩浆的形成、侵位时代,以及壳幔混合源等地球化学特征精细地约束了该区大石寨期岩浆活动的发育时间及过程,为研究西拉木伦缝合带晚古生代构造演化提供了新证据,同时也清晰地指示出古亚洲洋在晚古生代末期并不处于大洋俯冲阶段,而是造山后的伸展裂解阶段。     

Geochemistry and Tectonic History of Seamount Remnants in the Xingshuwa Subduction Accretionary Complex of the Xar Moron Area,Eastern Margin of the Central Asian Orogenic Belt

This study focuses on the geology, geochemistry, zircon U-Pb geochronology and tectonic settings of the three types of seamount basalts from the Xingshuwa subduction accretionary complex in the Xar Moron area, eastern margin of the Central Asian Orogenic Belt(CAOB). The seamount remnants are composed of carbonate 'cap' sediments, large volumes of pillow and massive basalts, carbonate breccia slope facies and radiolarian cherts. Group 1 basalts are characterized by high contents of P2 O5 and TiO2 with alkaline affinity and LREE enrichment, indicating that they are derived from intraplate magma. Group 2 basalts display N-MORB LREE depletion patterns, indicating that they were formed at a mid-ocean ridge. Group 3 basalts have shown distinct Nb depletion and high Th/Yb ratios, indicating that they were generated in an island arc tectonic setting. The zircon U-Pb age of Group 1 basalt sample XWT18-131 is 576.4 ± 9.4 Ma, suggesting that the oceanic island seamount was the product of intraplate magmatism related to a mantle plume or 'hot spot' in the late Neoproterozoic. The zircon U-Pb age of Group 2 basalt sample XWT18-132 is 483 ± 22 Ma, indicating that the Paleo-Asian Ocean(PAO) was continuously expanding in the Early Ordovician. The zircon U-Pb age of Group 3 basalt sample XWT18-101 is 240.5 ± 8.2 Ma, suggesting that this area underwent the evolutionary path of ocean-continent transition, developing towards continentalization during the Middle Triassic. Thus, we believe that there was both mantle plume-related intraplate magmatism and intraoceanic subduction during the evolution of the PAO, the CAOB possibly being an evolutionary model of an intraoceanic subduction and mantle plume magmatism complex.