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武夷地块北东部迪口地区下元岩体和红叶岗岩体锆石La-ICP-MS U-Pb年龄及其地质意义 总被引:1,自引:0,他引:1
迪口地区的下元岩体和红叶岗岩体位于武夷山地区东、西武夷俯冲碰撞增生杂岩带(450~440 Ma)中。我们对下元岩体中的三个岩石样品进行了锆石La-ICP-MS U-Pb测年,获得岩体的侵位结晶年龄分别为420±4 Ma、430±4 Ma和434±4 Ma,证明该岩体为加里东岩体,而非早期认为的印支期花岗岩。红叶岗岩体进行La-ICP-MS锆石U-Pb测年获得的年龄为398±4 Ma,表明红叶岗岩体为加里东晚期岩体,而非前人认为的燕山期花岗岩。结合武夷山地区最新的研究成果分析,我们认为迪口地区下元岩体和红叶岗岩体可能形成于东、西武夷地块碰撞后拉张裂解环境。迪口地区下元岩体和红叶岗岩体的侵位时代为武夷地块加里东期的构造演化提供了更进一步的时代约束。 相似文献
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内蒙古中部昌特敖包花岗闪长岩单颗粒锆石U—Pb定年 总被引:4,自引:0,他引:4
昌特敖包花岗闪长岩体位于内蒙古中部苏尼特左旗南部,该岩体高精度的单颗粒锆石U-Pb年龄为362±4Ma(MSWD=0.005),这说明该地区确实存在晚古生代中期花岗岩,据此年龄和前人资料可将苏尼特左旗南部形成于晚古生代中期的花岗岩类划分为南北两个花岗岩带. 相似文献
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青龙岩体位于冈底斯带北麓,是班戈-嘉黎岩浆岩带的重要组成部分。该岩体主要岩性为花岗闪长岩,形成于白垩纪早期,SHRIMP锆石U-Pb 206Pb/238U年龄加权平均值为123.1Ma±3.4Ma,该年龄反映了青龙花岗闪长岩体的侵位或结晶年龄。花岗闪长岩地球化学数据表明,该岩体具有正常的SiO2含量,较低的K2O/Na2O比值,为弱过铝质岩石。该岩体轻稀土元素较重稀土元素富集,负Eu异常较弱。在微量元素蛛网图上,该岩体表现出强烈的Nb、Ta、Ti、Y负异常,具有岛弧花岗岩的地球化学特征。通过初步研究,认为青龙花岗闪长岩形成于俯冲背景,为与板片俯冲作用有关的同熔型花岗岩。 相似文献
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青龙岩体位于冈底斯带北麓,是班戈-嘉黎岩浆岩带的重要组成部分。该岩体主要岩性为花岗闪长岩,形成于白垩纪早期,SHRIMP锆石U-Pb 206Pb/238U年龄加权平均值为123.1Ma±3.4Ma,该年龄反映了青龙花岗闪长岩体的侵位或结晶年龄。花岗闪长岩地球化学数据表明,该岩体具有正常的SiO2含量,较低的K2O/Na2O比值,为弱过铝质岩石。该岩体轻稀土元素较重稀土元素富集,负Eu异常较弱。在微量元素蛛网图上,该岩体表现出强烈的Nb、Ta、Ti、Y负异常,具有岛弧花岗岩的地球化学特征。通过初步研究,认为青龙花岗闪长岩形成于俯冲背景,为与板片俯冲作用有关的同熔型花岗岩。 相似文献
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赣南银坑矿田高山角花岗闪长岩SHRIMP U-Pb定年及其与成矿的关系 总被引:5,自引:1,他引:4
高山角花岗闪长岩体位于南岭成矿带东段之北部,南岭东西向构造与滨太平洋北北东向构造带的交汇复合部位。岩体产出于银坑贵多金属矿田内部,与区内金银铅锌铜的成矿作用密切相关。在矿田地质和岩体地质工作基础上,采用SHRIMP锆石U-Pb法对高山角花岗闪长岩进行了精确定年,获得岩体锆石年龄为(160±1)Ma,并存在(422±4)Ma的捕获岩浆锆石年龄,指示岩体形成于燕山早期,而并不是以往认为的早白垩纪。结合矿床地质资料,判断矿田内的贵多金属成矿作用与高山角岩浆活动同期,与赣南地区中生代(165~150 Ma)大规模钨锡成矿作用产于同一时期、同一构造背景,同属一个成矿系列。 相似文献
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金沙江缝合带是特提斯东段重要的缝合带之一,羊拉地区的金沙江缝合带处在青藏高原东构造结东侧,是研究金沙江古洋盆的碰撞闭合过程等构造事件的重要窗口。在前人工作的基础上,通过野外系统观察取样,结合花岗岩侵入体的锆石SHRIMP U-Pb年龄测定结果,对金沙江古洋盆的碰撞闭合过程做初步研究。结果表明,从南部加仁岩体的通吉格花岗闪长岩(加仁岩体之一部分),经中部的路农—里农—江边岩体的花岗闪长岩,到北部的贝吾花岗闪长岩,岩体的侵位年龄分别为通吉格(246.1±3.5) Ma、路农花岗闪长岩(238.1±5.3) Ma、里农花岗闪长岩(239.0±5.7) Ma、江边岗闪长岩(227.9±5.1) Ma和贝吾花岗闪长岩(213.6±6.9) Ma,表明金沙江缝合带的碰撞关闭是从南向北逐渐闭合的,闭合的时限可达33 Ma,但闭合碰撞不是连续而是幕式的,碰撞闭合作用主要发生在约246 Ma、239 Ma、228 Ma、213 Ma 4个幕次。里农大沟还出现222 Ma的辉绿岩脉,与江边岩体时间上较为接近,似乎表明江边岩体侵入时期本区处于局部拉张的构造背景。 相似文献
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材玛花岗岩体为班公湖-怒江成矿带西段日土-多不杂岩浆弧带的成矿岩体之一。对材玛岩体的中粒黑云二长花岗岩进行锆石LA-ICP-MS U-Pb同位素测试,结果为165.1±1.5Ma(n=17,MSWD=0.86);全岩Rb-Sr同位素年龄为163.5±2Ma(n=5),材玛岩体的形成年龄为163~165Ma(中侏罗世)。材玛岩体属于高钾钙碱性系列,ΣREE=109.5~225.2(10-6),LREE富集,LREE/HREE=2.37~7.77,并伴随Eu的亏损。微量元素特征表现为着强烈的Ba、Nb、P、Ti亏损和Th、U、Pb富集,以及Zr的弱亏损。材玛岩体为班-怒带向北俯冲作用的产物,为岛弧型岩浆岩,物质来源为俯冲带之上的地幔部分熔融,并有地壳物质混熔。 相似文献
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西藏邦铺大型斑岩钼-铜矿床二长花岗斑岩锆石SHRIMP定年及其地质意义 总被引:3,自引:1,他引:2
利用锆石U-Pb SHRI MP定年技术,测定了西藏冈底斯斑岩铜矿带东段邦铺斑岩钼铜矿床中二长花岗斑岩的年龄,获得该含矿岩体真实侵位年龄为13.9±0.3 Ma(MSWD=3.05),属于喜马拉雅晚期。邦铺二长花岗斑岩的形成时代介于冈底斯成矿带后碰撞期伸展构造环境的斑岩体的形成时代(12~18 Ma),该年龄的厘定进一步丰富了冈底斯带岩浆活动,并为整个冈底斯成矿带岩浆岩演化历史提供年代学数据和新的启示:可以认为其与冈底斯斑岩铜矿带具有相同的动力学背景,同属于大规模的快速爆发成矿作用过程。 相似文献
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岗讲铜钼矿床是西藏冈底斯成矿带中段典型的斑岩型矿床,岗讲矿床成岩成矿时代、岩浆演化过程及其与成岩成矿关系尚不明确,利用LA-ICP-MS锆石U-Pb定年方法对岗讲矿区主要岩体二长花岗斑岩、花岗闪长斑岩和英云闪长玢岩成岩时代进行研究,获得锆石U-Pb年龄加权平均值分别为16.6±0.3 Ma (MSWD=0.94,n=10)、16.1±0.2 Ma (MSWD=1.07,n=12)、14.4±0.4 Ma (MSWD=1.12,n=7);同时采用辉钼矿Re-Os同位素测年方法首次对岗讲矿床石英硫化物脉中的辉钼矿进行定年,获得12件辉钼矿Re-Os同位素模式年龄集中于13.24±0.20 Ma~13.55±0.22 Ma,加权平均年龄为13.4±0.1 Ma (MSWD=0.65),等时线年龄为13.6±1.6 Ma (MSWD=1.2).结果表明:(1) 岗讲矿区复式岩体侵入序列为含巨斑黑云二长花岗岩-二长花岗斑岩-花岗闪长斑岩-流纹斑岩 (深部定名为英云闪长玢岩),成岩时限为16.6~14.4 Ma,成矿时代为13.4 Ma左右,成岩成矿是一个连续的岩浆演化过程;(2) 辉钼矿中Re含量为155.4~171.1 μg/g,均值为162.9 μg/g,指示其成矿物质中有幔源成分的加入;(3) 矿床产出于中新世印度-亚洲大陆碰撞后伸展构造环境. 相似文献
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世界斑岩铜矿主要产于中生代一新生代环太平洋带、古特提斯带和古生代中亚—蒙古带,因为上述3带为聚合板块集中分布地区。中国西藏集中了金沙江聚合带、雅鲁藏布江聚合带和怒江—班公错聚合带,为世界上聚合板块最发育地区之一,具有较长的大洋板块俯冲和陆—陆碰撞的造山历史,构造—花岗质岩浆十分发育,其中深源高侵位的花岗质斑岩分布广泛,对于形成斑岩铜矿和其他相关矿床十分有利,为找矿评价斑岩铜(金)矿很有前景的地区。笔者借鉴世界和中国评价斑岩铜矿的经验,同时收集了西藏近年来找寻评价斑岩铜矿有关的地质资料,对西藏斑岩铜矿的前景进行了展望。 相似文献
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大巴山与雪峰山逆冲构造带J3-K1复合过程的响应———鄂西秭归褶皱带构造样式与形成机制 总被引:1,自引:0,他引:1
秭归褶皱带位于大巴山逆冲带与雪峰山逆冲带叠合部位,总体呈现穹窿-盆地型式,是构造复合、联合作用的结果,记录了大巴山逆冲带与雪峰山逆冲带两者相互作用的重要信息,是研究构造复合和联合过程的理想区域。本文通过对秭归褶皱带秭归向斜、巴东复向斜和香龙山背斜的野外调查,对褶皱枢纽、相关断层、节理等进行详细构造解析,理清了先后叠加关系,在此基础上进行了构造分期和配套,对变形期古构造应力场进行了恢复重建。结果表明秭归褶皱带晚侏罗世-早白垩世经历三期构造变形:D1期以近EW向的秭归向斜和香龙山背斜为代表,秭归向斜为轴面近直立的开阔圆弧状,香龙山背斜呈轴面近直立的箱状,相关逆冲断层具由北向南逆冲的特点,可能与大巴山由NE向SW逆冲作用有关。D2期秭归向斜叠加近SN向枢纽,呈锅状,香龙山背斜东段发育鼻状的五龙背斜,褶皱带呈穹窿-盆地型。与向斜相关的水田坝断裂带向SEE逆冲,主压应力场呈NWW-SEE近平行的束状。该期变形可能与雪峰山逆冲带向NW逆冲过程中受到黄陵背斜阻挡有关。D3期秭归向斜近SN向枢纽向南西弯曲,巴东复向斜呈NW凸出弧形,香龙山背斜西端叠加NE-SW向构造形迹。主压应力场总体向NW发散。该期变形可能与雪峰山逆冲带向NW逆冲推挤有关。上述构造分析表明,向SW逆冲的大巴山逆冲带先影响鄂西地区,之后向NW逆冲推挤的雪峰山逆冲带扩展至该地区,形成复合关系。区域构造与地层关系分析表明D1-D3形成于J3-K1,因此秭归褶皱带是大巴山逆冲构造带向SW叠瓦逆冲并与指向NW的雪峰山逆冲带复合叠加的结果,表明上扬子地区在J3-K1经历了分阶段复合叠加的过程,即前期受到大巴山逆冲带近SN构造作用影响,后期经历向NW逆冲推挤的雪峰山逆冲带NW-SE向构造叠加。 相似文献
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扎格罗斯褶皱冲断带是扎格罗斯碰撞造山带的前陆褶皱冲断带,也是波斯湾周缘前陆盆地的楔顶带,自北东到南西垂直于构造线方向可分为高扎格罗斯冲断带和扎格罗斯简单褶皱带;自北西到南东沿构造线方向可分为洛雷斯坦区(Lorestan)、迪兹富勒湾区(Dezful Embayment)和法尔斯区(Fars)。扎格罗斯褶皱冲断带的形成始于晚白垩世阿拉伯板块的洋壳向北俯冲到欧亚板块之下,褶皱冲断构造从北东部缝合带向南西方向伸展,并在上新世基本定型。本文选取了横切扎格罗斯褶皱冲断带的3条地质剖面和两条局部地震剖面进行构造变形分析。剖面分析显示研究区垂向上由一条大滑脱面将扎格罗斯褶皱冲断带剖面分为上、下两个构造层;褶皱冲断变形从北东到南西向由强变弱。研究区发育走滑、挤压和拉张3种构造变形,挤压构造变形占主导地位。挤压构造变形又包括滑脱褶皱、断展褶皱、断弯褶皱和双重构造等。 相似文献
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Geotectonic subdivision and areal extent of the Sangun belt, Inner Zone of Southwest Japan 总被引:8,自引:0,他引:8
Y. NISHIMURA 《Journal of Metamorphic Geology》1998,16(1):129-140
The Sangun belt has long been considered to be a major coherent glaucophanitic terrane of Permian to Triassic age, and to be paired with the low-P/T Hida belt to the north. However, recent progress in geochronology, metamorphic geology, and tectonics has revealed that the belt is in fact comprised of two geologic units of different ages and with contrasting conditions of formation. The older unit is named the Renge belt and the younger the Suo belt. The Renge belt is the oldest of the high-P/T metamorphic belts in the Japanese Islands and extends from northern Kyushu, through the San-in coastal regions, to the Hida marginal belt. It is characterized by 330–280 Ma ages and the association of glaucophane–schist to epidote–amphibolite facies schists. The Renge belt is also typically associated with meta–ophiolite sequences (470–340 Ma) including serpentinite. The Suo belt is characterized by 230–160 Ma high-P/T schists closely related to weakly metamorphosed Permian accretionary rocks of the Akiyoshi belt. Metamorphic facies series is from the prehnite–pumpellyite facies through the pumpellyite–actinolite and glaucophane–schist facies to the epidote–amphibolite facies. The belt is widespread in west Kinki to north and central Kyushu via Chugoku, but also stretches further to the southwest and is present in the Ishigaki-Iriomote Islands of the southern Ryukyu Arc. Throughout this belt, there are scattered small blocks or lenses of meta–ophiolite, whose K–Ar ages of relict hornblendes are 590 to 220 Ma. Bounded by low-angle faults and thrusts, both belts define subhorizontal nappes dipping gently north. The geotectonic framework in the Inner Zone of Southwest Japan is made up of, from north to south, the Hida-Oki, Renge, Akiyoshi, Suo, Maizuru plus ultra-Tamba, Mino-Tamba, and Ryoke belts, with a tectonically downward-younging polarity. This has resulted from stepwise accretions during Palaeozoic to Mesozoic time. 相似文献
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The Occidental terrane of the central segment of the Brasiliano-Pan-African Ribeira belt comprises two crustal scale thrust sheets (Andrelândia and Juiz de Fora domains) taken as reworked Neoproterozoic products of the São Francisco cratonic margins. Pre-1.8 Ga orthogneisses and associated rocks of the Mantiqueira Complex comprise the basement for rocks of the Andrelândia Depositional Cycle within the Andrelândia tectonic domain. Geochemical data indicate that the Mantiqueira Complex comprises rocks that can be grouped as follows: intermediate to acid calc-alkaline rocks and a transitional basaltic series. On the basis of quantitative analysis of the lithogeochemical data, these lithotypes cannot be related. Statistical and/or petrological criteria made it possible to define suites and/or groups within each one of those units and to constrain petrogenetic models based mostly on their REE data. Simple least-square regression analysis indicates that the basic rocks are unlikely to constitute a single suite themselves. The results of the geochemical modelling presented in this work suggest that crustal partial melting rather than fractional crystallisation is the most likely petrogenetic process associated with the rocks of the Mantiqueira Complex. The partial melting processes might have taken place under oxidising conditions, typical of tectonic settings associated with the generation of calc-alkaline rocks. 相似文献
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In central Shikoku, SW Japan, the Mikabu belt is bounded to the north by the Sanbagawa belt, and to the south by the northern (N) Chichibu belt. The N-Chichibu belt can be further subdivided into northern and southern parts. There is no apparent difference in the overall geology, structure, or fossil and radiometric ages between the Mikabu belt and the northern part of the N-Chichibu belt. Greenstones from the Mikabu belt and the northern part of the N-Chichibu belt show evidence for similar low-grade metamorphism, and include the following mineral assemblages with albite+chlorite in excess: metamorphic aragonite, sodic pyroxene+quartz, epidote+actinolite+pumpellyite, glaucophane+ pumpellyite+quartz, and lawsonite (not with actinolite or glaucophane). These similarities suggest that the Mikabu belt and the northern part of the N-Chichibu belt belong to the same geological unit (the MB-NNC complex). The mineral assemblages also indicate that the MB-NNC complex belongs to a different metamorphic facies from the low-grade part of the Sanbagawa belt, that is, the former represents lower temperature/higher pressure conditions than the latter. Structural and petrological continuity between the MB-NNC complex and Sanbagawa belt has not yet been confirmed, but both have similar radiometric ages. It is therefore most likely that the MB-NNC complex and Sanbagawa belt belong to the same subduction complex, and were metamorphosed under similar but distinct conditions. These two units were juxtaposed during exhumation. In contrast, the southern part of the N-Chichibu belt is distinct in lithology and structure, and includes no mineral assemblages diagnostic of the MB-NNC complex and the Sanbagawa belt. Thus, the southern part of the N-Chichibu belt may represent a different geological unit from the MB-NNC complex and Sanbagawa belt. 相似文献
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通过野外地质考察和地震资料解释,将龙门山褶皱冲断带划分为5个构造带,即青川-茂汶断裂以西为松潘-甘孜构造带,青川-茂汶断裂与北川-映秀断裂之间为韧性变形带,北川-映秀断裂与马角坝-通济场-双石断裂之间为基底卷入冲断带,马角坝-通济场-双石断裂与广元-关口-大邑断裂之间为前缘-褶皱冲断带,广元-关口-大邑断裂以东为前陆坳陷带,在构造变形特征上,各条断裂在演化上具有前展式特征,在松潘-甘孜构造带和韧性变形带构造变形强烈,形成推覆构造带等构造变形样式,在前缘-褶皱冲断带和前陆坳陷带,变形强度较弱,形成背冲断块或断层相关褶皱等构造,西北部区域的变形表现为塑性变形特征,向南东方向渐变为塑-脆性变形和脆性变形,在剖面上各条断裂所形成的深度向盆地方向逐渐递减。龙门山褶皱冲断带的分带性变形特征是由多种因素共同影响的结果,这些因素主要有板块构造背景的决定作用、多套滑脱层的控制作用和岩性因素的制约作用。 相似文献
20.
吉林-黑龙江高压变质带的初步厘定:证据和意义 总被引:14,自引:11,他引:3
本文定义的吉林-黑龙江高压变质带是指我国东北地区佳木斯-兴凯地块西缘和南缘共同发育的呈弧形展布的高压变质带,具体包括佳木斯-兴凯地块西缘增生杂岩带(黑龙江蓝片岩带和张广才-小兴安岭增生杂岩带)和佳木斯-兴凯地块南缘的长春-延吉增生杂岩带.其中佳木斯-兴凯地块西缘增生杂岩带形成于晚三叠-早侏罗世(180 ~ 210Ma),为佳木斯-兴凯地块向西冲增生而形成的高压变质带;而长春-延吉增生杂岩带由一系列特征性俯冲-增生杂岩组成,包括石头口门-烟筒山红帘石片岩带、呼兰群变质杂岩、色洛河群变质杂岩、青龙村群变质杂岩和开山屯变质杂岩等,形成时代为187~230Ma,峰期为220~230Ma.长春-延吉增生杂岩带曾被认为是西拉木伦河断裂带的东延部分,但是区域构造分析表明,它们形成的动力学背景与佳木斯-兴凯地块西缘增生杂岩带相同,均为太平洋板块三叠纪-早侏罗世的西向俯冲导致佳木斯-兴凯地块自东向西的“剪刀式”闭合过程.我们将佳木斯-兴凯地块西缘和南缘发育的三叠纪-早侏罗世增生杂岩带作为统一的构造单元来考虑,结合该区发育有典型的高压变质带,因此命名为“吉林-黑龙江高压变质带,简称吉黑高压带”.吉黑高压带形成于太平洋板块三叠纪-早侏罗世的西向俯冲导致佳木斯-兴凯地块自东向西的“剪刀式”闭合的过程,同时该带记录了古亚洲构造域的结束和太平洋俯冲开始的关键时期,为两大构造域叠加与转换的关键性地质证据. 相似文献