阿尔巴尼亚布尔齐泽壳-幔过渡带豆荚状铬铁矿成因及其对富Ti熔体交代作用的记录          下载免费PDF全文

邱添  杨经绥  吴魏伟  熊发挥  芮会超  蒋久阳 《沉积与特提斯地质》2021,41(3):485-504

豆荚状铬铁矿是关键金属铬的重要来源之一,尽管豆荚状铬铁矿的研究取得了诸多进展,但对于发育于蛇绿岩壳-幔过渡带的铬铁矿成因却涉及较少.阿尔巴尼亚布尔齐泽岩体壳-幔过渡带中产出的Cerruja豆荚状铬铁矿矿床,其矿体及纯橄岩围岩普遍被辉石岩脉穿切,辉石岩脉与矿体接触带以及辉石岩脉中的铬尖晶石强烈破碎,在铬尖晶石的裂隙和包裹...  相似文献   

黑龙江三十二站金矿床地质地球化学特征及构造环境     

侯晓光  叶松青  杨言辰  李向文  晋海滨  李明飞  郝宇杰 《世界地质》2013,32(3):492-504

三十二站金矿床位于黑龙江省漠河县西北部额尔古纳隆起北东端上黑龙江断陷盆地边缘。矿体赋存于二十二站组中粒砂岩--泥质岩中,岩浆岩以闪长玢岩、花岗岩为主,与成矿关系密切。矿区内共发现9 条矿化蚀变带,10 条金矿体,矿体长600 ～ 1 290 m,宽1. 86 ～ 5. 70 m,金品位( 1. 31 ～ 2. 44) × 10 － 6。构造环境判别图解表明,区内花岗岩为造山类花岗岩,具与俯冲带有关的陆缘环境或岛弧构造环境特征。闪长玢岩具有岛弧和活动大陆边缘弧岩浆岩的特征; 二十二站组砂岩具有大陆岛弧的构造环境特征。结合区域地质演化特征,认为在中侏罗世末—晚侏罗世早期,古太平洋板块斜向俯冲于西伯利亚板块下部,二十二站组砂岩中的金元素初次富集,并为成矿提供有利空间。晚侏罗世后期中--酸性岩浆侵入,流体与地幔相互作用,导致地幔金属硫化物被氧化分解带至地表浅部,最后在成矿有利部位成矿。  相似文献   

佳木斯地块东北缘早二叠世六连岩体的岩浆混合成因：岩相学、年代学和地球化学证据   总被引：9，自引：6，他引：3  

于介江  侯雪刚  葛文春  张彦龙  柳佳成 《岩石学报》2013,29(9):2971-2986

本文报道了佳木斯地块东北缘六连岩体中主岩花岗闪长岩和暗色微粒包体的岩相学、锆石U-Pb年代学、全岩地球化学以及锆石Hf同位素资料,以确定该岩体的形成时代、岩石成因及其构造属性。主岩花岗闪长岩和暗色微粒包体中角闪辉长岩分别获得了284Ma 和278Ma 的成岩年龄,表明六连岩体形成于早二叠世而非前人认为的晚印支期。包体具有岩浆结构,部分包体存在塑性流变特征,包体中可见淬冷边、反向脉和针状磷灰石,包体和主岩中均发育矿物异常共生或不平衡结构,结合主岩和包体的年代学和地球化学特征可以判定六连岩体为早二叠世岩浆混合作用的产物。全岩地球化学和锆石Hf同位素特征揭示出,六连岩体中主岩和包体的原始岩浆分别起源于新元古代增生的深部陆壳基性火成岩和受俯冲流体交代的亏损地幔楔的部分熔融。结合同时代火成岩组合的空间变异特征以及区域构造演化历史,认为佳木斯地块东北缘早二叠世六连岩体形成于活动大陆边缘环境,其地球动力学机制与佳木斯地块东侧古洋板块的西向俯冲作用有关。  相似文献   

Role of chemical processes on shear zone formation: an example from the Grimsel metagranodiorite (Aar massif,Central Alps)     

P. GONCALVES  E. OLIOT  D. MARQUER  J. A. D. CONNOLLY 《Journal of Metamorphic Geology》2012,30(7):703-722

Alpine deformation in the Grimsel granodiorite (Aar massif, Central Alps) at greenschist facies conditions (6.5 ± 1 kbar for 450°C ± 25°C) is characterized by the development of a network of centimetre to decametre localized shear zones that surround lenses of undeformed granodiorite. Localization of deformation is assumed to be the result of a first stage of extreme localization on brittle precursors (nucleation stage) followed by a transition to ductile deformation and lateral propagation into the weakly deformed granodiorite (widening stage). A paradox of this model is that the development of the ductile shear zone is accompanied by the crystallization of large amounts of phyllosilicates (white mica and chlorite) that maintains a weak rheology in the localized shear zone relative to the host rock so that deformation is localized and prevents shear zone widening. We suggest that chemical processes, and more particularly, the metamorphic reactions and metasomatism occurring during re‐equilibration of the metastable magmatic assemblage induced shear zone widening at these P–T–X conditions. These processes (reactions and mass transfer) were driven by the chemical potential gradients that developed between the thermodynamically metastable magmatic assemblage at the edge of the shear zone and the stable white mica and chlorite rich ultramylonite formed during the first stage of shear zone due to localized fluid infiltration metasomatism. P–T and chemical potential projections and sections show that the process of equilibration of the wall rocks (μ–μ path) occurs via the reactions: kf + cz + ab + bio + MgO + H₂O = mu + q + CaO + Na₂O and cz + ab + bio + MgO + H₂O = chl + mu + q + CaO + Na₂O. Computed phase diagram and mass balance calculations predict that these reactions induce relative losses of CaO and Na₂O of ～100% and ～40% respectively, coupled with hydration and a gain of ～140% for MgO. Intermediate rocks within the strain gradient (ultramylonite, mylonite and orthogneiss) reflect various degrees of re‐equilibration and metasomatism. The softening reaction involved may have reduced the strength at the edge of the shear zone and therefore promoted shear zone widening. Chemical potential phase diagram sections also indicate that the re‐equilibration process has a strong influence on equilibrium mineral compositions. For instance, the decrease in Si‐content of phengite from 3.29 to 3.14 p.f.u, when white mica is in equilibrium with the chlorite‐bearing assemblage, may be misinterpreted as the result of decompression during shear zone development while it is due only to syn‐deformation metasomatism at the peak metamorphic condition. The results of this study suggest that it is critical to consider chemical processes in the formation of shear zones particularly when deformation affects metastable assemblages and mass transfer are involved.  相似文献   

佳木斯地块东部二叠纪锦山花岗杂岩体的成因及其地质意义   总被引：9，自引：0，他引：9  

毕君辉  葛文春  张彦龙  杨浩  王智慧 《地球科学与环境学报》2014,(4)

报道了佳木斯地块东部锦山花岗杂岩体的锆石LA-ICPMS U-Pb定年结果、全岩地球化学和锆石Hf同位素特征,确定了花岗质岩石的形成时代、源区性质及其地球动力学背景,同时也为中亚造山带东段的构造演化提供重要线索。花岗岩的锆石主要呈自形—半自形晶,发育显著的震荡生长环带,w(Th)/w(U)值在0.12~1.20之间,显示其典型的岩浆成因。测年结果表明这些花岗质岩石形成于早—中二叠世(260~278 Ma)。地球化学特征显示:花岗质岩石w(SiO2)值为66.75%~70.10%,w(Na2O)值为4.40%~5.23%,w(K2O)值为0.77%~2.80%,w(K2O)/w(Na2O)值为0.18~0.61,A/CNK值为0.97~1.14;这些岩石富集大离子亲石元素(Rb、Ba和K),相对亏损高场强元素(Nb、Ta、P、Zr、Ti和Hf)。锆石原位Hf同位素分析显示,花岗岩的εHf(t)值介于-0.8~7.7之间,两阶段Hf模式年龄介于953~1 578Ma之间。该区花岗质岩石属于偏铝质—弱过铝质的低钾—中钾钙碱性I型花岗岩,原始岩浆起源于中—新元古代增生的下地壳物质的部分熔融。结合区域研究资料,研究区内早—中二叠世花岗岩就位于活动大陆边缘环境,其形成可能与佳木斯地块东侧古大洋板块的西向俯冲作用有关。  相似文献   

蒙古-鄂霍茨克洋俯冲的记录：额尔古纳地区八大关变质杂岩的证据   总被引：4，自引：1，他引：3  

曾维顺  周建波  董策  曹嘉麟  王斌 《岩石学报》2014,30(7):1948-1960

本文对额尔古纳地块西缘八大关杂岩进行了锆石LA-ICP-MS U-Pb定年和岩石地球化学分析,以确定该套杂岩的形成时代及其构造属性。原定义为"佳疙瘩组"的八大关杂岩主要由黑云角闪斜长片麻岩和花岗质糜棱岩组成。LA-ICP MS锆石U-Pb研究表明,3个样品的锆石发育典型的岩浆振荡环带,高Th/U(0.13~1.42),轻稀土元素亏损,重稀土元素富集,具有强烈的正Ce异常和强烈的负Eu异常等特征,表明锆石均属于岩浆成因。测年结果表明2个黑云角闪斜长片麻岩形成时代分别为210±2Ma、214±2Ma,花岗质糜棱岩的原岩年龄为203±3Ma;样品中同时存在~501Ma和~795Ma的捕获/继承锆石。上述结果显示八大关杂岩的形成时代应为晚三叠世而不是前人认为的新元古代,而捕获锆石则显示与东北其它地块具有相同的构造演化历史。地球化学研究显示,八大关杂岩具有高钠、铝等特点,A/CNK=0.86~1.05,A/NK=1.53~1.97,为准铝质到弱过铝质钙碱性系列;轻稀土元素富集、重稀土元素亏损(La/Yb)N=6~31,Eu弱亏损(Eu/Eu*=0.50~1.01),具有较高的Sr含量(在378×10-6~598×10-6之间)及低的Yb含量(在0.71×10-6~3.50×10-6之间);微量元素原始地幔标准化蛛网模式图显示,富集Rb、Ba、K及Sr等大离子亲石元素、强烈亏损Nb、Ta、P、Ce及Ti等高场强元素。这些地球化学特征表明八大关杂岩形成于活动大陆边缘的岛弧环境。因此,八大关杂岩应形成于蒙古-鄂霍茨克洋向额尔古纳地块俯冲的大地构造背景,为蒙古-鄂霍茨克洋在三叠纪晚期南向俯冲提供了关键证据。  相似文献   

Characterization of Quartzites in the Southern Korean Peninsula     

Yongin Kim  Yong Il Lee 《Gondwana Research》2003,6(4):729-742

In the southern Korean Peninsula twelve quartzite strata occur in the Gyeonggi massif and Okcheon belt. Their geologic ages range from Precambrian to Upper Paleozoic. All quartzites in the Gyeonggi massif are of Precambrian in age and are characterized by high-grade metaquartzites; they are Seosan, Anyang, Yongmunsan and Uiam quartzites from west to east. Quartzite types occurring in the Okcheon belt are diverse from orthoquartzite to medium-grade metaquartzite. Orthoquartzites are all Paleozoic in age and are distributed mainly in the eastern Okcheon belt (Taebaeksan Basin) (Jangsan, Dongjeom and Jeongseon quartzites) with one in the central Okcheon belt (Mungyeong Quartzite). Low-grade metaquartzite is Hwasan quartzite in the western part and medium-grade metaquartzites are Daehyangsan and Geumsusan quatzites in the central part, and Yongamsan quartzite in the southwestern part of the Okcheon belt. Distribution of quartzite types in the southern Korean Peninsula is not related to the geologic age of quartzites. As a case study, quartzite characteristics were applied to a provenance study of quartzite clasts in the northwestern part of the Cretaceous Gyeongsang Basin. Quartzite clasts in the study area are interpreted to have been mostly derived from source quartzites in the Okcheon belt, which is consistent with the results of previous studies.  相似文献   

GEOTECTONICS CHARACTERISTICS AND THEIR RELATION WITH GAS-OIL POOL FORMATION OF THE DONGSHA FAULT-UP LIFTED MASSIF   总被引：1，自引：0，他引：1  

刘昭蜀  魏常兴  赵岩  杨树康  陈森强 《中国海洋湖沼学报》1992,10(3):193-203

The Dongsha fault- uplifted massif (for convenience . Dongsha massif from here on) is located in the northern continental shelf-slope of the South China Sea, where the water depth is 100-400m. The massif is considered to be a part of the large-scale fault-uplifted zone directed NE and separating the Pearl River Mouth Basin into northern and southern graben areas. The sedimentary cover of the Pearl River Mouth Graben consists mainly of a 7000-10000m thick Tertiary system. A large-scale uplift occurred in the Dongsha fault-uplifted zone during Paleocene-Eocene when the lower structural layer (lower Tertiary) existed only in the small depressions of the fault-uplifted zone. The formation and evolution of the Dongsha fault-uplifted zone could be divided into: 1) the basement formation stage (J2-K1); 2) the slowly uplifted stage (K2-E22); 3) the weathering and erosion stage (E23-E31); 4) the integrated subsidence stage (E32-N12) and 5) the last uplifted stage (N13-Q). The formation of the oil and gas pools o  相似文献   

柴达木盆地北缘全吉地块东端变基性岩体LA-ICP-MS锆石U-Pb年龄：中元古代陆块裂解的证据     

廖梵汐  龚松林  董彦君  王勤燕  张璐  陈能松 《中国区域地质》2012,(8):1279-1286

全吉地块东端古元古代二长花岗片麻岩中普遍发育变质的基性岩体,它们的形成时代、变质作用时代和对地块基底构造演化的指示意义尚不清楚。应用LA-ICP-MS技术测定其中的一个变基性岩体的锆石U-Pb年龄,获得的10个测点数据显示,锆石受到热事件的强烈改造而发生严重铅丢失,但拟合的不一致线仍给出相关性较好的上交点年龄1712Ma±47Ma和下交点年龄472Ma±29Ma,MSWD=1.4。这表明,变质基性岩的原岩形成于中元古代早期,是全吉地块在古元古代末期汇入Columbia超大陆之后于中元古代早期初始裂解而侵位的基性岩体。这些基性岩体在早古生代卷入了柴北缘碰撞带而发生角闪岩相变质作用,并受到构造肢解。  相似文献   

Seismogenic Structure around the Epicenter of the May 12, 2008 Wenchuan Earthquake from Micro‐seismic Tomography   总被引：1，自引：0，他引：1  

AN Meijian  FENG Mei  DONG Shuwen  LONG Changxing  ZHAO Yue  YANG Nong  ZHAO Wenjin  ZHANG Jizhong 《《地质学报》英文版》2009,83(4):724-732

Abstract: A three-dimensional local-scale P-velocity model down to 25 km depth around the main shock epicenter region was constructed using 83821 event-to-receiver seismic rays from 5856 aftershocks recorded by a newly deployed temporary seismic network. Checkerboard tests show that our tomographic model has lateral and vertical resolution of ~2 km. The high-resolution P-velocity model revealed interesting structures in the seismogenic layer: (1) The Guanxian-Anxian fault, Yingxiu-Beichuan fault and Wenchuan-Maoxian fault of the Longmen Shan fault zone are well delineated by sharp upper crustal velocity changes; (2) The Pengguan massif has generally higher velocity than its surrounding areas, and may extend down to at least ~10 km from the surface; (3) A sharp lateral velocity variation beneath the Wenchuan-Maoxian fault may indicate that the Pengguan massif’s western boundary and/or the Wenchuan-Maoxian fault is vertical, and the hypocenter of the Wenchuan earthquake possibly located at the conjunction point of the NW dipping Yingxiu-Beichuan and Guanxian-Anxian faults, and vertical Wenchuan-Maoxian fault; (4) Vicinity along the Yingxiu-Beichuan fault is characterized by very low velocity and low seismicity at shallow depths, possibly due to high content of porosity and fractures; (5) Two blocks of low-velocity anomaly are respectively imaged in the hanging wall and foot wall of the Guanxian-Anxian fault with a ~7 km offset with ~5 km vertical component.  相似文献