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西昆仑库地蛇绿混杂岩由方辉橄榄岩和纯橄榄岩等地幔变质橄榄岩、豆荚状铬铁矿、堆晶橄榄岩、堆晶辉石岩和辉长岩、辉绿岩墙、块状和枕状玄武岩等组成。强亏损方辉橄榄岩为主的地幔岩组合,二辉石的低Al含量和铬尖晶石的高Cr#,以及岩石的富Mg、Ni和贫Al、Ca特征一致表明地幔橄榄岩类是经较高程度部分熔融后的地幔残余,与消减带之上蛇绿岩中的同类岩石相近。岩石富Rb、Ba、U、Th、LREE,说明地幔残余岩石受到了来自消减带的洋壳重熔组分的混染。堆晶岩以辉石岩和辉长岩为主,可能属PPG系列,指示岩浆是在消减带环境和含水条件下熔融的。辉长岩为低Ti蛇绿岩型,代表洋内弧后盆地早期环境或弧前环境。辉绿岩和玄武岩为洋中脊拉斑玄武岩和岛弧拉斑玄武岩的过渡类型;玄武岩和辉绿岩相比富Ba、Th、LREE,贫Ta,指示玄武岩较辉绿岩更多地受到来自消减带洋壳重熔组分的影响。库地蛇绿岩形成时的古构造环境是消减带之上的弧间或弧后盆地。 相似文献
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本文通过对泽当蛇绿岩中地幔橄榄岩主要矿物的矿物化学,以及蛇绿岩中地幔橄榄岩、玄武岩和辉长岩的岩石化学和地球化学的研究,结合前人对泽当蛇绿岩年代学和构造背景的认识,讨论泽当蛇绿岩的起源和演化。①通过对泽当蛇绿岩地幔橄榄岩中橄榄石的Fo值,斜方辉石和单斜辉石的En值、Mg#值和Al2O3含量,尖晶石的Mg#和Cr#值的讨论,发现泽当蛇绿岩地幔橄榄岩起源于洋中脊下亏损地幔域,方辉橄榄岩的熔融程度比二辉橄榄岩高,后期都受到俯冲带的改造。②通过对地幔橄榄岩岩石化学和地球化学分析,绝大多数的主量元素和微量元素的含量低于原始地幔,微量元素的原始地幔标准化曲线与深海橄榄岩曲线重合,说明它们是亏损的原始地幔熔融残留物,起源于洋中脊环境。③通过对泽当蛇绿岩辉长岩的岩石化学和地球化学研究发现辉长岩起源于比N-MORB更亏损的源区,具有N-MORB的性质,后期可能因为受到俯冲带的改造又具有了岛弧拉斑玄武岩的性质。④泽当蛇绿岩玄武岩包含N-MORB型和E-MORB型两类,说明泽当蛇绿岩起源于包含富集地幔的岩浆源区。N-MORB型玄武岩还具有岛弧拉斑玄武岩的性质,说明N-MORB型玄武岩后期受到俯冲带的改造,而EMORB型玄武岩没有受到俯冲带影响。⑤通过总结前人对泽当蛇绿岩年代学和构造背景的研究成果以及本文的发现,作者认为泽当蛇绿岩是170Ma左右起源于混合不均一的洋中脊下亏损地幔域,150Ma左右在弧前环境受到俯冲带的改造。 相似文献
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阿尔金山中段清水泉-茫崖蛇绿构造混杂岩带地质特征 总被引:6,自引:1,他引:5
清水泉—茫崖蛇绿构造混杂岩带沿阿尔金山南坡分布,呈醒目的“绿色岩带”,其主要由蛇绿岩、蛇绿岩上覆岩系和元古代外来岩片或岩块组成,现多为构造透镜体,蛇绿岩上覆岩系具远洋深海沉积特征;岩石地球化学资料研究证明,蛇绿岩中的玄武岩与洋内岛弧拉斑玄武岩相似;同位素测年结果显示蛇绿岩形成于早古生代,蛇绿岩源自亏损的软流圈地幔,同时有富集地幔物质加入,暗示早古生代研究区曾出现过小洋盆构造环境。 相似文献
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对新疆西准噶尔达尔布特蛇绿岩套柳树沟镁铁质杂岩中橄榄辉长岩、蛇纹石化橄榄辉长岩、辉长岩和蚀变辉长岩地球化学分析表明:辉长岩和蚀变辉长岩具有钙碱性和拉斑玄武岩的双重特征,橄榄辉长岩和蛇纹石化橄榄辉长岩属镁铁质堆积岩,为蛇绿岩组成单元;稀土总量较高,具微弱正Eu异常,稀土元素配分模式为略左倾平坦型,与SSZ型镁铁质堆晶岩稀土配分模式相同;微量元素蛛网图上,富集大离子亲石元素Cs、K、Th、U,相对亏损高场强元素Nb、Ta,可能代表俯冲板片的流体交代上覆地幔楔使地幔岩石发生部分熔融。地球化学构造环境判别柳树沟镁铁质岩石岩浆源区为亏损型地幔向富集型地幔过渡的适度富集型地幔,其形成的最佳模型是在成熟岛弧基础上裂谷化形成的一个不成熟的类似边缘海性质弧后盆地,不具成熟大洋或盆地那样的洋壳-上地幔结构,在盆地扩张初期岩浆具岛弧特征,随着盆地被进一步打开,镁铁质岩石具N-MORB特征。对辉长岩采用SHRIMP锆石U-Pb同位素年龄测试,获得特柳树沟镁铁质岩石的结晶时间为314.9±1.7 Ma。 相似文献
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新疆东准噶尔克拉麦里蛇绿岩地球化学:洋脊俯冲的产物 总被引:5,自引:5,他引:5
新疆东准噶尔克拉麦里蛇绿岩中的镁铁质岩兼具有洋中脊玄武岩(MORB)和岛弧拉斑玄武岩(IAB)的特征,岩石地球化学特征表现为轻稀土(LREE)亏损、平坦或略微富集,不同程度地亏损高场强元素(HFSE)而富集大离子亲石元素(LILE),成分上非常相似于受洋脊俯冲影响的 Chile Ridge 和 Cocos Ridge 玄武岩。可以认为其可能形成于受洋脊俯冲影响的岛弧或弧前扩张环境。相对较高的ε_(Nd)(t)(7.2~9.8)、低 Nb/Zr、Ta/Yb 比值,说明在洋脊俯冲的影响下,其源区可能存在有至少三种组分:弧下地幔、来自消减板片流体和俯冲沉积物、MORB 地幔。 相似文献
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西藏丁青蛇绿岩的东杂岩体是一种与玻镁安山岩(Boninite)有关的特殊的蛇绿岩类型。其 堆晶斜方辉石岩、辉长岩和辉绿岩的岩石化学、微量元素以及稀土元素的地球化学特征均与西太平洋诸岛(伊豆—马利亚纳、巴布亚新几内亚、新喀里多尼亚等)的玻镁安山岩相似。此外,超镁铁质构造岩中的橄榄石和顽火辉石富镁,指示残余地幔具强烈亏损的性质。尖晶石的Cr含量中等至较高,与深海橄榄岩及大洋中脊玄武岩中的尖晶石不同。堆晶岩和辉长岩中的古铜辉石富镁,斜长石富钙,也明显不同于典型大洋中脊环境的特征,表明丁青东蛇绿岩形成的环境不像大洋中脊或弧后盆地,而可能是在洋内俯冲带之上的岛弧底部。 相似文献
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《现代地质》2017,(3)
西藏果芒错蛇绿岩位于狮泉河—纳木错—波密蛇绿混杂岩带的中段,主要由地幔橄榄岩、铁镁质-超铁镁质堆晶杂岩、枕状熔岩、基性岩墙和硅质岩等单元组成。对果芒错蛇绿混杂岩中超铁镁质堆晶岩、基性岩岩石学及地球化学特征的研究表明,果芒错超铁镁质堆晶杂岩具很好的堆晶韵律,岩石化学特征反映了随着Mg O含量的降低其从底到顶的连续分离结晶过程;堆晶杂岩稀土元素总体上具LREE富集、Eu轻微异常特点,微量元素具有富集高场强元素、亏损大离子亲石元素的特征,且相容元素显示良好的变化规律,指示岩石来自受富集组分混染的地幔源区,并在后期经历了俯冲流体作用。果芒错基性岩具有富集型洋中脊玄武岩(E-MORB)叠加岛弧型玄武岩(IAB)的地球化学特征,并受到后期俯冲流体的影响。根据果芒错蛇绿岩地球化学属性及其构造环境判别图解,推断该地区蛇绿岩生成于扩张的弧后盆地构造环境。作为狮泉河—纳木错—波密蛇绿岩带的一部分,该区蛇绿岩以班公湖—怒江特提斯洋弧后盆地的形式存在。 相似文献
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岩石化学、地球化学资料表明,古太古代陈台沟蛇绿岩由绿泥滑石片岩和蛇纹岩(橄榄岩)、角闪岩类岩石(拉斑玄武岩)、石英岩(远洋深海硅质岩)组成,它们具备蛇绿岩套层序的基本特征,可能为古太古代洋壳残片.陈台沟蛇绿岩具有贫硅、贫碱、低钛,而富铁、镁,稀土总量很低的特点.微量元素分析结果表明该蛇绿岩中的玄武岩富集K、Rb、Ba等大离子亲石元素,亏损Nb、Hf等高场强元素,具有岛弧型火山岩的特点,其在稀土元素球粒陨石标准化配分图解中主要显示平坦型曲线.陈台沟蛇绿岩的形成环境可能为岛弧环境. 相似文献
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西藏雅鲁藏布江缝合带西段东波蛇绿岩的构造背景特征 总被引:2,自引:0,他引:2
西藏东波蛇绿岩位于雅鲁藏布江缝合带西段,由地幔橄榄岩、辉石岩和辉长岩等组成。地幔橄榄岩主要为方辉橄榄岩、纯橄岩和少量二辉橄榄岩。岩体的边界出露玄武岩和硅质岩等。地幔橄榄岩中有少量辉石岩和辉长岩的脉岩,宽约1 m,走向北西,与岩体的构造线方向基本一致。各岩相岩石地球化学研究结果表明,东波蛇绿岩的岩相存在较大的差异,玄武岩具有与洋岛玄武岩(OIB)相似的地球化学特征,而地幔橄榄岩中辉石岩、辉长岩脉与洋中脊玄武岩(MORB)相似,形成于洋中脊环境,并受后期俯冲流体作用的改造。东波岩体中二辉橄榄岩具有与深海地幔橄榄岩较一致的轻稀土亏损特征,而方辉橄榄岩和纯橄岩的地球化学特征显示出岩体形成于MOR环境,后受到SSZ环境的改造。东波蛇绿岩的岩石地球化学特征显示其洋中脊叠加洋岛的构造背景。 相似文献
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中天山北缘干沟蛇绿混杂岩带的地质地球化学 总被引:7,自引:3,他引:7
中天山北缘干沟蛇绿混杂岩带主要由属于弧前火山-沉积岩系的混杂基质及其襄胁的构造岩块组成,后者主要包括蛇绿岩残块、岛弧火山岩残块,以及大理岩、花岗岩等外来构造岩块。并因蛇绿岩及岛弧火山岩的出露而成为古板块缝合带的标志。干沟蛇绿岩岩石组合出露较为齐全,包括变质橄榄岩(蛇纹岩)、辉长岩、辉绿岩、玄武岩等构造岩块,但几乎均呈零散的构造岩块,散布于混杂基质中。变质橄榄岩以相对低SiO_2、TiO_2、Al_2O_3和CaO、高MgO为特征,类似于大洋中脊二辉橄榄岩主元素化学组成;∑REE低,LREE亏损,富集Cr、Ni,与世界典型蛇绿岩的超镁铁单元岩石地球化学特征类似。玄武岩的地球化学研究表明其以中等TiO_2、高MgO,不具有Nb、Ta亏损和Th富集为特征;与MORB相比较,高场强元素(HSFE)丰度低且平坦不分异;与原始地幔相比较,具有类似于N-MORB的亏损地幔特征,主、微量元素的地球化学特征显示岩石应形成于洋中脊构造环境。岛弧型火山岩出露于混杂岩带南部,主要为橄榄粗安岩;主元素以高MgO、Al_2O_3、K_2O、Na_2O、K_2O/Na_2O≈1、低TiO_2和CaO含量,富含挥发份为特征。同时,富集大离子亲石元素Rb、Ba、zr、Th、U和LREE等,并以Nb、Ta亏损和Th富集显示其成因与消减作用有关,形成于板块俯冲过程中的活动大陆边缘火山弧环境。干沟区段的混杂岩因存在蛇绿岩和与俯冲作用有关的火山岩而厘定为蛇绿混杂岩带,并指示沿中天山北缘曾存在古洋盆及其俯冲消减作用。 相似文献
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西藏吉定蛇绿岩地球化学特征及其构造指示意义 总被引:3,自引:2,他引:1
吉定蛇绿岩位于雅鲁藏布江蛇绿岩带的中段,是该带保存较好的蛇绿岩之一,通过对该岩体的研究及与附近蛇绿岩剖面的对比有助于恢复早白垩世雅鲁藏布江蛇绿岩带的演化过程。吉定蛇绿岩包括玄武岩、辉绿岩、堆晶岩及地幔橄榄岩四个岩石单元。壳层岩石岩浆结晶顺序为:橄榄石→单斜辉石→斜长石,代表湿岩浆系统分异。吉定蛇绿岩壳层熔岩(玄武岩和辉绿岩)Ti O2含量为0.87%~1.45%,平均1.1%,与印度洋N-MORB玻璃(1.19%)相似。REE配分模式具有明显的LREE亏损特征,稀土配分模式与典型的大洋中脊玄武岩相似。但其微量元素蛛网图上表现为富集LILE,而亏损HFSE,并具有较高LILE/HFSE比值特征,与俯冲带上的(SSZ)蛇绿岩相似。蛇绿岩熔岩在岩石地球化学上表现出既亲MORB,又具部分IAB的特征。结合区域上大竹卡、得几等蛇绿岩岩石及地球化学资料对比分析,提出吉定蛇绿岩形成于在洋内俯冲带上发育起来的弧后盆地,并提出日喀则地区早白垩世洋壳演化的解释模式:雅鲁藏布江中段蛇绿岩至少包含三种组分特征的蛇绿岩体,其代表性剖面分别是吉定,得村和大竹卡,分别形成于近俯冲带的弧后盆地、弧前盆地和弧后盆地,这些洋壳共同组成早白垩世时期的与特提斯洋俯冲带斜交的一条分段发育的洋中脊。 相似文献
14.
元古代蛇绿岩及铬铁矿 总被引:2,自引:1,他引:1
本文总结了国外典型元古代蛇绿岩的岩石组合、野外产状、地球化学资料以及成矿特征,并与显生宙蛇绿岩进行了对比,继而探讨元古代板块构造演化和铬铁矿成因。资料表明,早元古代和中-新元古代均有蛇绿岩的存在,但前者较少,仅见于Canadian地盾的Cape Smith Belt中的Prutuniq蛇绿岩(2. 05~2. 0Ga)和芬兰Fennoscandian地盾的Outokumpu和Jormua蛇绿岩(时代为1. 97~1. 96Ga),而中-新元古代的蛇绿岩则见于世界许多地区,如埃及东部沙漠区(~750Ma)和非洲东北部地区(ca.900~800Ma)等。与显生宙蛇绿岩相比,这些老蛇绿岩具如下特征:(1)它们均为被肢解的蛇绿岩,大多与"弧火山岩"和(或)混杂岩伴生,经历不同程度的变形和变质(具绿片岩相-角闪岩相组合);(2)岩石组合大多较齐全,壳层组合发育,以镁铁-超镁铁岩(堆晶岩)、辉长岩、镁铁质席状岩床(墙)杂岩、火山岩为代表;层状镁铁-超镁铁岩的韵律层以及矿物的隐晶变化等均提示了岩浆多期次活动及开放岩浆房的特征;(3)元古代蛇绿岩中既有高铝型铬铁矿,也有高铬型铬铁矿,且主要寄主于纯橄岩(或蛇纹岩)中;高铝型和高铬型直接受控于熔体的熔融程度及含水流体的参与,反映了铬铁矿形成于俯冲带演化的不同阶段;铬铁矿规模均较小,且均以低TiO 2为特征,均为岩浆分异作用的产物,明显区别于显生宙熔融残余成因的豆荚状铬铁矿;(4)元古代蛇绿岩常伴有硫化物Cu-Co-Zn-Au矿,且铬铁矿含Zn较高(Zn=0. 11%~0. 18%)(如芬兰Outokumpu蛇绿岩);橄榄岩及铬铁矿中常含较高的MnO (高达1. 79%,如埃及东部的Wizer蛇绿岩);(5)元古代蛇绿岩具多种成因:主要为俯冲带成因(如埃及蛇绿岩、北东非蛇绿岩、芬兰Outokumpu蛇绿岩),少量为洋中脊成因(加拿大Purtuniq蛇绿岩)及裂谷成因(芬兰Jormua蛇绿岩)等。 相似文献
15.
青藏高原西部蛇绿岩类型:岩石学与地球化学证据 总被引:22,自引:0,他引:22
对青藏高原西部地区的班公湖蛇绿岩、狮泉河蛇绿岩、雅鲁藏布江西段蛇绿岩和普兰—当穷蛇绿岩带中代表性岩体的地质学、岩石化学、稀土元素、微量元素、Pb、Sr同位素地球化学研究表明,青藏高原西部地区4条蛇绿岩中的地幔橄榄岩主要为方辉橄榄岩和少量纯橄岩,岩石化学成分具有富镁、贫铝、钙、碱的特点;论述了地幔橄榄岩轻稀土元素富集是由于先经历了较强的部分熔融,后经历了俯冲消减过程中的流体交代的二次过程;微量元素中大离子亲石元素Rb、不活动元素Nb、Zr、Hf和放射性生热元素Th等元素的丰度较高,以及Ti、Sm、Y、Yb等强不相容元素亏损的特点,与交代地幔岩特征类似;Pb、Sr同位素组成具有明显的壳源组分混入的特点,说明青藏高原西部的蛇绿岩曾受洋壳俯冲消减过程中的流体交代作用,蛇绿岩产于SSZ构造环境。对比青藏高原东部、三江、西昆仑地区以及形成于典型的SSZ环境的Troodos蛇绿岩中的地幔橄榄岩,就岩石化学富MgO、轻稀土元素富集而言,它们具有与青藏高原西部基本一致的地质地球化学特征,结合与俯冲岩浆作用有关的玻安岩和埃达克岩产出,说明可能包括三江、西昆仑库地在内的青藏高原不同时代蛇绿岩都主要形成于俯冲消减环境,属于SSZ型蛇绿岩。 相似文献
16.
Island arc elements and arc-related ophiolites 总被引:1,自引:0,他引:1
Evan C. Leitch 《Tectonophysics》1984,106(3-4)
All major structural elements in island arc systems, fore-arc, magmatic arc, back-arc basins and remnant arcs, are potential ophiolite sources, and those features that allegedly characterise ophiolites of ocean-ridge origin, sheeted dyke complexes, mantling pelagic rocks, hydrothermal metamorphism and associated mineralization, can also arise within arc settings. Age relations are critical in the interpretation of arc-related ophiolites. Remnants of oceanic lithosphere, identified by a pre-arc initiation age, are restricted to fore-arc, magmatic arc and remnant arc elements, as are ophiolite masses generated at the inception of underthrusting. The latter, apparently common in ancient fore-arc terrains, form in nascent arc systems in which the rate of role back of the subduction hinge exceeds the rate of convergence. Spreading occurs above a foundering slab resulting in some arc-like compositional features. In simple arc systems later ophiolitic rocks have formed either in the active back-arc basin or the magmatic arc. Only those ophiolites that have resided within or very close behind magmatic arcs should show calcalkaline or arc tholeiite magmatic affinities, or be intruded or overlain by these rocks. Volcanic-derived sediment or pelagic material may mantle ophiolites from all arc settings, but pelagic rocks will generally dominate in stratigraphic sequences above remnant arcs and on back-arc basin floors except adjacent to the magmatic arc. Ophiolites generated at major ocean ridges are unlikely to be immediately overlain by sediment with a significant volcanic component whereas such detritus may lie directly on arc-inception, arc and back-arc ophiolites. Some arc-derived ophiolites are preserved in their original tectonic position, others can be identified from their internal features, their relationship to other tectonic elements, and the nature of associated rocks. 相似文献
17.
拜韦尔特半岛矿产资源主要包括铜、金和石棉,区域地层和构造是控制矿床形成、发展和叠加改造的主要因素。这些矿产资源主要赋存在拜韦尔特海洋带达利吉带圣母玛利亚亚带的早奥陶世潜次火山岩中,包括起源于超俯冲作用带的蛇绿岩套和火山岩盖层。其蛇绿岩套超镁铁堆积岩的热液蚀变岩中产出石棉,火山成因的块状硫化物型(VMS型)铜±金矿产在基性和双峰式火山岩中,金矿产在基性和超基性的热液蚀变岩中。而蛇绿岩套火山岩盖层中则产出与条带状含铁建造(BIF)有关的后生金矿,石英脉型或相关的交代型矿床则大多赋存在蚀变和变形的基性岩中。拜韦尔特半岛的构造样式和几何结构非常复杂。 相似文献
18.
The Late Ordovician Solund-Stavfjord ophiolite in western Norway represents a remnant of the Iapetus oceanic lithosphere that developed in a Caledonian marginal basin. The ophiolite contains three structural domains that display distinctively different crustal architecture that reflects the mode and nature of magmatic and tectonic processes operated during the multi-stage seafloor spreading evolution of this marginal basin. Domain I includes, from top to bottom, an extensive extrusive sequence, a transition zone consisting of dike swarms with screens of pillow breccias, a sheeted dike complex, and plutonic rocks composed mainly of isotropic gabbro and microgabbro. Extrusive rocks include pillow lavas, pillow breccias, and massive sheet flows and are locally sheared and mineralized, containing epidosites, sulfide-sulfate deposits, Fe-oxides, and anhydrite veins, reminiscent of hydrothermal alteration zones on the seafloor along modern mid-ocean ridges. A fossil lava lake in the northern part of the ophiolite consists of a >65-m-thick volcanic sequence composed of a number of separate massive lava units interlayered with pillow lavas and pillow breccia horizons. The NE-trending sheeted dike complex contains multiple intrusions of metabasaltic dikes with one- and two-sided chilled margins and displays a network of both dike-parallel normal and dike-perpendicular oblique-slip faults of oceanic origin. The dike-gabbro boundary is mutually intrusive and represents the root zone of the sheeted dike complex. The internal architecture and rock types of Domain I are analogous to those of intermediate-spreading oceanic crust at modern mid-ocean ridge environments. The ophiolitic units in Domain II include mainly sheeted dikes and plutonic rocks with a general NW structural grain and are commonly faulted against each other, although primary intrusive relations between the sheeted dikes and the gabbros are locally well preserved. The exposures of this domain occur only in the northern and southern parts of the ophiolite complex and are separated by the ENE-trending Domain III, in which isotropic to pegmatitic gabbros and dike swarms are plastically deformed along ENE-striking sinistral shear zones. These shear zones, which locally include fault slivers of serpentinite intrusions, are crosscut by N20°E-striking undeformed basaltic dike swarms that contain xenoliths of gabbroic material. The NW-trending sheeted dike complex in the northern part of Domain II curves into an ENE orientation approaching Domain III in the south. The anomalous nature of deformed crust in Domain III is interpreted to have developed within an oceanic fracture zone or transform fault boundary.REE chemistry of representative extrusive and dike rocks from all three domains indicates N- to E-MORB affinities of their magmas with high Th/Ta ratios that are characteristic of subduction zone environments. The magmatic evolution of Domain I encompasses closed-system fractional crystallization of high-Mg basaltic magmas in small ephemeral chambers, which gradually interconnected to form large chambers in which mixing of primary magmas with more evolved and fractionated magma caused resetting of magma compositions through time. The compositional range from high-Mg basalts to ferrobasalts within Domain I is reminiscent of modern propagating rift basalts. We interpret the NE-trending Domain I as a remnant of an intermediate-spread rift system that propagated northeastwards (in present coordinate system) into a pre-existing oceanic crust, which was developed along the NW-trending doomed rift (Domain II) in the marginal basin. The N20°E dikes laterally intruding into the anomalous oceanic crust in Domain III represent the tip of the rift propagator. The inferred propagating rift tectonics of the Solund-Stavfjord ophiolite is similar to the evolutionary history of the modern Lau back-arc basin in the SW Pacific and suggests a complex magmatic evolution of the Caledonian marginal basin via multi-stage seafloor spreading tectonics. 相似文献
19.
The Makran accretionary prism in southeastern Iran contains extensive Mesozoic zones of melange and large intact ophiolites, representing remnants of the Tethys oceanic crust that was subducted beneath Eurasia. To the north of the Makran accretionary prism lies the Jaz Murian depression which is a subduction-related back-arc basin. The Band-e-Zeyarat/Dar Anar ophiolite is one of the ophiolite complexes; it is located on the west side of the Makran accretionary prism and Jaz Murian depression, and is bounded by two major fault systems. The principal rock units of this complex are a gabbro sequence which includes low- and high-level gabbros, an extensive sheeted diabase dike sequence, late intrusive rocks which consist largely of trondhjemites and diorites, and volcanic rocks which are largely pillow basalts interbedded with pelagic sedimentary rocks, including radiolarian chert. Chondrite- and primitive-mantle-normalized incompatible trace element data and age-corrected Nd, Pb, and Sr isotopic data indicate that the Band-e-Zeyarat/Dar Anar ophiolite was derived from a midocean ridge basalt-like mantle source. The isotopic data also reveal that the source for basalts was Indian-Ocean-type mantle. Based on the rare earth element (REE) data and small isotopic range, all the rocks from the Band-e-Zeyarat/Dar Anar ophiolite are cogenetic and were derived by fractionation from melts with a composition similar to average E-MORB; fractionation was controlled by the removal of clinopyroxene, hornblende and plagioclase. Three 40Ar–39Ar plateau ages of 140.7±2.2, 142.9±3.5 and 141.7±1.0 Ma, and five previously published K–Ar ages ranging from 121±4 to 146±5 Ma for the hornblende gabbros suggest that rocks from this ophiolite were formed during the Late Jurassic–Early Cretaceous. Plate reconstructions suggest that the rocks of this complex appear to be approximately contemporaneous with the Masirah ophiolite which has crystallization age of (150 Ma). Like Masirah, the rocks from the Band-e-Zeyarat/Dar Anar ophiolite complex represent southern Tethyan ocean crust that was formed distinctly earlier than crust preserved in the 90–100 Ma Bitlis-Zagros ophiolites (including the Samail ophiolite). 相似文献
20.
准噶尔北部蛇绿岩形成时限新证据及其东、西准噶尔蛇绿岩的对比研究 总被引:30,自引:13,他引:17
准噶尔北部出露有塔尔巴哈台库吉拜蛇绿岩、洪古勒楞-和布克赛尔蛇绿岩及扎河坝-阿尔曼太蛇绿岩。洪古勒楞蛇绿岩中的堆晶辉长岩样品进行SHRIMP U-Pb定年,结果为472±8.4Ma(MSWD=1.4),限定洪古勒楞-和布克赛尔蛇绿岩形成于早奥陶世。对扎河坝蛇绿岩中斜长花岗岩采用SHRIMP U-Pb方法测定年龄为495.9±5.5Ma(MSWD=2.7),证实扎河坝蛇绿岩形成于晚寒武世-早奥陶世。塔尔巴哈台蛇绿岩、和布克赛尔-洪古勒楞蛇绿岩以及扎河坝-阿尔曼太蛇绿岩均在早奥陶世已经形成,大部分以断层侵位的形式侵位于泥盆纪-石炭系火山-沉积地层中。准噶尔北部东西三段蛇绿岩在形成时代、区域地质以及地球物理特征等方面具有可对比性,认为它们构成一条贯穿东、西准噶尔的蛇绿岩带,这为新疆北部及邻区古生代构造格局的重建以及区域构造的对比连接提供了重要信息。 相似文献