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1.
西藏日喀则地区德村-昂仁蛇绿岩内基性岩的元素与Sr-Nd-Pb同位素地球化学及其揭示的特提斯地幔域特征 总被引:4,自引:7,他引:4
系统研究了西藏雅鲁藏布江蛇绿岩带中部日喀则地区德村、吉丁和昂仁蛇绿岩中基性岩石的元素与 Sr-Nd-Pb 同位素地球化学特征。这些基性岩石,包括玄武岩、辉长岩和辉绿岩,属于低钾拉斑玄武岩系列,球粒陨石标准化稀土元素分配模式为轻稀土元素亏损的 N-MORB 型,(La/Yh)_N=0.31~0.65(除样品 DC993为1.17)。在原始地幔标准化微量元素图上,亏损高度不相容元素,与 N-MORB 配分模式一致。相对于 Th,无 Nb、Ta的亏损,显示样品不是产于 SSZ 环境。经构造环境图解判别,样品落入了 N-MORB 区域内;这些元素成分特征表明样品具有洋中脊环境或成熟的弧后盆地环境属性。Sr、Nd 和 Pb同位素组成特征表明特提斯地幔源区以 DM(亏损地幔)为主,同时存在少量 EMⅡ(富集地幔类型Ⅱ)、Sr,Nd 和 Pb 同位素组成特征还表明特提斯地幔域具有印度洋 MORB 型的 Sr-Nd-Pb 同位素组成特征。本文的结果进一步支持 Zhang et al.(2005)的研究结果,现今印度洋不仅在地理位置上占据了曾经是特提斯洋的大部分,而且它的地幔域还继承了曾经特提斯的地幔域的地球化学特征。 相似文献
2.
新疆达拉布特蛇绿岩带玄武岩地球化学特征:古亚洲洋与特提斯洋的对比 总被引:13,自引:7,他引:6
发育在我国北部的古亚洲洋构造域和西南部的特提斯构造域是中国境内最重要的两个构造体系,有关这两个构造域的地幔地球化学特征是揭示它们的演化与交接关系的重要课题之一。本文选择发育在新疆西准噶尔地区达拉布特蛇绿岩带中阿克巴斯套和大棍的枕状玄武岩进行了系统的岩石学和地球化学与Sr-Nd-Pb同位素地球化学研究,结果表明,达拉布特蛇绿岩带中枕状玄武岩具有N-MORB和E-MORB特征,可能形成于大洋中脊环境。岩石的~(87)Sr/~(86)Sr为0.682112~0.706040之间;~(143)Nd/~(144)Nd为0.512713~0.512879,ε_(Nd)(t)= 2.8~ 5.1,~(206)Pb/~(204)Pb、~(207)Pb/~(204)Pb和~(208)Pb/~(204)Pb的变化范围分别是18.341~20.085、15.541~15.651和38.292~40.534。将达拉布特玄武岩的微量元素特征比值、Nd-Pb同位素等与印度洋MORB和太平洋与北大西洋MORB,以及已知的特提斯和古亚洲洋地幔域进行对比表明,达拉布特蛇绿岩单元内MORB型玄武岩与特提斯构造域特蛇绿岩单元内MORB型玄武岩同位素特征一致,都显示了印度洋型的MORB特征。这意味着位于现今新疆西准噶尔地区的古亚洲洋地幔域没有显示出与特提斯不同的典型的太平洋和北大西洋的地球化学特征。 相似文献
3.
西藏雅鲁藏布蛇绿岩形成构造环境的地球化学鉴别 总被引:9,自引:7,他引:2
本文对西藏雅鲁藏布蛇绿岩带中部日喀则地区夏鲁蛇绿岩中的基性岩石进行了元素地球化学研究。岩石为低钾亚碱性玄武质岩石,具有低TiO2(0.64%~1.5%)、低K2O(<0.69%)、富Na2O(2.5%~6.0%)、烧失量普遍较高(2.0%~7.5%)的特征,表明样品普遍遭受蚀变。岩石具有与N-MORB类似的稀土元素和总体一致的微量元素特征,但是岩石明显富集大离子亲石元素和亏损高场强元素,显示了洋脊玄武岩向着岛弧岩浆作用的过渡趋势。日喀则蛇绿岩不是典型的洋中脊成因,应为SSZ型蛇绿岩,可能形成于与洋内俯冲有关的SSZ型的弧后或者弧前盆地中。对东西延伸超过1500km的雅鲁藏布蛇绿岩246套基性岩石形成的构造环境进行的地球化学判别,表明至少存在大陆岛弧型、地幔柱-洋内热点型、洋中脊-大洋岛弧型和典型大洋岛弧型等四种类型洋壳,揭示了特提斯洋存在多种构造环境的特征,有利于恢复和还原一个长期演化的、丰富的特提斯洋。 相似文献
4.
通过对日喀则蛇绿岩的镁铁质岩石进行岩石学和地球化学研究,探讨其岩石成因及源区性质,同时根据Re-Os同位素的地球化学约束来探索雅鲁藏布蛇绿岩的形成机制。研究表明,日喀则蛇绿岩镁铁质岩石微量元素的标准化配分型式与洋中脊玄武岩类似,又具有岛弧玄武岩的地球化学特征。结合微量元素和同位素特征,均表明岩石的形成与俯冲作用有关。日喀则蛇绿岩产出于远离大陆地壳的SSZ环境,其形成过程未受到陆壳的混染;同时,Re-Os同位素体系受蚀变作用的影响也不明显。日喀则蛇绿岩镁铁质岩石的Re、Os含量低,187Os/188Os同位素比值较高,主要是源区性质和俯冲作用影响的结果。特提斯洋早期发生的多次俯冲作用造成地幔源区不均一。新特提斯洋壳俯冲过程中,上述不均一地幔发生部分熔融产生的镁铁质岩浆上升,经过遭受了早期熔体/岩石作用的纯橄岩通道,发生强烈的Re-Os同位素分馏,使熔体与地幔残余Os同位素组成表现出明显的解耦现象,进而形成现今的日喀则蛇绿岩。 相似文献
5.
青藏高原东北缘特提斯构造域界线的探讨 总被引:8,自引:3,他引:8
东特提斯构造域北界的确定不仅可以约束构造域的范围及演化,而且对于约束中国各陆块的原始构造归属也有着非常重要的意义.本文将从地球化学角度对这一科学问题进行探讨.祁连造山带早古生代蛇绿岩单元内枕状玄武岩的元素、Sr-Nd-Pb同位素组成系统研究表明:其地幔源区的Nd和Pb同位素组成均表现出印度洋MORB型同位素组成特征;枕状玄武岩(△^207Pb/^204Pb)t变化范围为9.1~24.3(平均值为14.7),(△^208/^204Pb)t变化范围为9.1~101.1(平均值55.3);与古特提斯和新特提斯蛇绿岩具有一致的同位素组成.因此,祁连造山带古洋幔应属于原特提斯构造域.纵观中国境内的特提斯构造域蛇绿岩的分布特征可知:该构造域表现出自北而南变年轻的时空演化规律,从而说明中央造山带的动力学过程也应纳入冈瓦纳大陆裂解和亚洲增生的总动力学系统之中. 相似文献
6.
西藏南部雅鲁藏布构造带分布有一系列蛇绿岩体。人们对这些蛇绿岩体的形成环境仍然存在较大的争议。雅鲁藏布构造带中段日喀则蛇绿岩路曲和大竹曲岩体镁铁质岩石的微量元素和Pb同位素特征指示其母岩浆起源于亏损地幔源区。这些镁铁质岩石的La/Sm和Sm/Yb比值显示其岩浆产生于尖晶石二辉橄榄岩地幔经过大约10%部分熔融作用。综合岩相学和全岩主量元素特征暗示这些镁铁质岩石形成于无水玄武质岩浆。而且这些镁铁质岩石的微量元素和REE元素配分模式均非常相似于N-MORB,除了弱Nb-Ta负异常。这些特征表明路曲和大竹曲岩体形成于大洋中脊环境。此外,路曲和大竹曲镁铁质岩石的Pb同位素结果指示其地幔源区与印度洋MORB地幔域具有相似的地球化学特征。这些镁铁质岩石N-MORB标准化微量元素模式显示弱Nb-Ta负异常可能是由于其地幔源区交代了古老的俯冲带物质。 相似文献
7.
西秦岭-松潘构造结古洋地幔地球化学特征及构造归属探讨 总被引:2,自引:0,他引:2
西秦岭-松潘构造结是中国大陆中重要的构造转换域,为探讨不同陆块及古洋幔的构造归属提供了非常有利的条件。该构造结早古生代蛇绿岩单元内变质玄武岩的地球化学特征表明:其源区不具有高场强元素(HFSE)相对于大离子亲石元素(LILE)亏损的特征;稀土元素(REE)及其它不活泼元素特征表明蛇绿岩形成于与岛弧无关的环境。变质玄武岩的 Sr 同位素组成受到海水热液蚀变或后期变质作用的影响而有所改变。Nd-Pb 同位素组成特征表明其地幔源区具有典型的印度洋MORB 型同位素组成特征(传统意义上的"Dupal"异常),从而说明其地幔源区属于原特提斯构造域。西秦岭-松潘构造结古洋幔构造归属的研究不仅为研究该构造结内各微陆块构造归属提供重要的约束,也为研究有关陆块间造山带的性质、发展与演化提供了动力学背景。 相似文献
8.
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
9.
内蒙古温都尔庙和巴彦敖包-交其尔蛇绿岩的元素与同位素地球化学:对古亚洲洋东部地幔域特征的限制 总被引:2,自引:5,他引:2
内蒙古中部发育的三条蛇绿岩带是华北板块和西伯利亚板块之间的缝合带。本文系统研究了其中的温都尔庙和巴彦敖包-交其尔两个蛇绿岩带中变质玄武岩的元素和 Sr、Nd、Pb 同位素地球化学。苏右旗温都尔庙碱性玄武岩为轻稀土富集型;岩石具有板内和大陆裂谷区玄武岩的特征,可能代表了600Ma 左右,温都尔庙地区开始发育的新洋盆。采自苏左旗的巴彦敖包-交其尔玄武岩分为两类,一类呈现轻稀土富集型,呈洋岛玄武岩特征;另一类具有明显的 Nb、Ta 负异常,显示大洋岛弧玄武岩特征,洋岛玄武岩的存在表明古亚洲洋曾经发育洋盆,大洋岛弧玄武岩的存在表明古亚洲洋内部有大洋岩石圈之间的俯冲。将本文的古亚洲洋洋岛玄武岩与中国西南地区的特提斯洋岛玄武岩进行系统的元素和同位素地球化学特征对比表明,古亚洲洋的洋岛玄武岩显示高 U/Pb(HU)和北大西洋和太平洋省的特征,而特提斯洋岛玄武岩属于印度洋省。这些说明古亚洲洋地幔域与特提斯地幔域是两个独立的构造域,它们代表了长期演化的两个不同的地幔地球化学域。 相似文献
10.
藏南特提斯喜马拉雅带内江孜-康马地区白垩纪多期基性岩浆作用 总被引:3,自引:3,他引:0
在特提斯喜马拉雅带东部江孜-康马一带发育大量近东西向展布的辉绿岩体/墙,研究表明这些基性岩至少可分为三期:(1)形成于~140Ma的辉绿岩具有OIB型地球化学特征,部分样品Sr-Nd同位素组成与其东部~132Ma错美-班布里大火成岩省中基性岩相当,部分高镁样品具有Nb-Ta负异常和Pb正异常,εNd(t)值小于0;(2)形成于~120Ma的辉绿岩显示N-MORB型地球化学特征;(3)形成于~90Ma的辉绿岩显示E-MORB型地球化学特征。后两期基性岩的Sr-Nd同位素组成均显示与印度洋MORB相关。结合同时期的Kerguelen地幔柱活动轨迹及东冈瓦纳大陆裂解事件,本文认为江孜-康马地区~140Ma基性岩代表Kerguelen地幔柱及其与上覆东冈瓦纳大陆岩石圈地幔相互作用产物,是Kerguelen地幔柱长期潜伏于东冈瓦纳大陆下的证据,在前人研究基础上将该地幔柱影响的范围从错美向西拓展了约200km;之后随着东冈瓦纳大陆裂解和印度洋的开启及扩张,印度板块逐渐北移并远离Kerguelen地幔柱,江孜-康马地区~120Ma和~90Ma两期基性岩代表新生印度洋软流圈部分熔融的产物,与Kerguelen地幔柱无关。该区识别出的三期基性岩浆活动表明:特提斯喜马拉雅带的东部在白垩纪经历了与东冈瓦纳大陆裂解、印度洋的开启和扩张相关的多期基性岩浆活动。这些基性岩为深入了解和限定特提斯喜马拉雅带自140Ma以来的古地理位置和构造演化过程提供了新的岩石记录和时间坐标。 相似文献
11.
The geodynamic setting of the Xigaze ophiolite has long been debated. Structural and geochemical evidence suggest the Xigaze ophiolite was formed at a slow‐spreading ridge (Nicolas et al., 1981; Liu et al., 2016). Based on incompatible element concentrations, the Xigaze ophiolite volcanics are consistent with the ubiquitous subduction signature in suprasubduction zone (Bedard et al., 2009; Hebert et al., 2012; Dai et al., 2013). It is noteworthy that the Xigaze ophiolite is different from the Geotimes and Lasail and Velly units from Oman ophiolite, respectively. The mafic rocks of the Xigaze ophiolite generally resemble typical N‐MORB and Geotimes volcanics in composition except for slight depletions of Th and Nb (Fig.1a). Although the Xigaze rocks have similar Th and Nb concentrations to Lasail and Velly rocks, most incompatible elements in the Xigaze rocks are comparable to N‐MORB. Petrography in gabbro of Xigaze ophiolite shows that euhedral plagioclases are enclosed by clinopyroxenes suggesting that these minerals have crystallized from an anhydrous magma (Sisson and Grove, 1993). Although the Xigaze volcanic rocks are slightly depleted in Th and Nb, they have MORB‐like trace element characteristics implying that they are derived from an anhydrous MORB magma at spreading centre. Godard et al. (2006) suggested that the mantle source of the Oman ophiolite have element and isotopic characteristics similar to Indian Ocean MORB, where the mantle preserved some older slab materials. A negative Nb anomaly of Oman Geotimes volcanic rocks may be resulted from contamination of the slab materials via decompression melting of the convecting mantle. Moreover, the Xigaze rocks have 1.27–3.18 of (Th/Nb)N ratios similar with those of Geotimes volcanics ((Th/Nb)N =0.51–2.77) and lower than those of Lasail and Velly units ((Th/Nb)N =2.12–6.35). These features suggest that the Xigaze ophiolite may have formed at the spreading centre. 相似文献
12.
The Xigaze ophiolite is located in the middle section of the Yarlung Zangbo River ophiolite belt and includes a well-preserved sequence section of seven ophiolite blocks. The relatively complete ophiolitic sequence sections are represented by Jiding, Dejixiang, Baigang, and Dazhuqu ophiolites and consist of three–four units. The complete ophiolite sequence in order from the bottom to top consists of mantle peridotite, cumulates, sheeted sill dike swarms, and basic lavas±radiolarian chert. These cumulates are absent in the remaining blocks of Dejixiang and Luqu. The age of radiolaria in the radiolarian chert is Late Jurassic–Cretaceous. The basalt and ultramafic rock of the ophiolite also are overlaid by Tertiary Liuqu conglomerate, which contains numerous pebble components of ophiolite, indicating that the Tethys Ocean began to close at the end of Cretaceous Period. The isotopic data of gabbro, diabase, and albite granite in the Xigaze ophiolite are approximately 126–139 Ma, which indicates that the ophiolite formed in the Early Cretaceous. The K–Ar age of amphibole in garnet amphibolite in the ophiolite mélange is 81 Ma, indicating that tectonic ophiolite emplacement occurred at the end of Late Cretaceous. 相似文献
13.
It is unclear why the Pb, Nd, and Sr isotopic composition of the modern mid-ocean ridge basalts (MORB) from the Indian Ocean is different from that of the North Atlantic and Pacific Oceans. A possible explanation for this is that the Indian MORB-type isotopic signature is a long-lived regional feature of the mantle, as evidently shown by the isotopic composition of the 350 Ma MORB-like Mian-Lue northern ophiolite, which was formed in the same region presently occupied by the Indian Ocean. However, this hypothesis is in conflict with the lack of Indian MORB-type isotopic signature in a number of 150 Ma Tethyan and Indian Ocean crusts. To further constrain the origin of the Indian MORB-type isotopic signature, we analyze the geochemical and Pb, Nd, and Sr isotopic composition of representative mafic rocks from four Tethyan ophiolites ranging in age from 90 to 360 Ma. The Sr isotopic composition of the samples is unreliable due to alteration, but the age-corrected Nd and Pb isotopic ratios and geochemical data indicate that these Tethyan rocks were derived from a geochemically depleted asthenospheric source that had a clear Indian MORB-type isotopic signature. We therefore conclude that the bulk of the Indian suboceanic mantle was most probably inherited from the Tethyan asthenosphere. A few regions in both the Tethyan and Indian Oceans, however, are most probably underlain by Pacific and North Atlantic MORB-type mantle (and vice-versa) because of the flow of the asthenosphere in response to tectonic plate reorganizations that lead to openings and closures of ocean basins. The Indian MORB-type isotopic signature of the western Pacific marginal basin crusts could be due to either flow of the Indian Ocean mantle into the western Pacific or to endogenous production of such an isotopic signature from delaminated East-Asian sublithospheric materials during closure of the Tethys Ocean. 相似文献
14.
准噶尔古大洋作为古亚洲洋北部的重要分支及阶段性演化产物,其洋盆的俯冲、闭合时限以及盆地基底属性一直存在分歧。本文选取准噶尔盆地东北缘(乌伦古地区)石炭系火山岩来说明其岩浆来源及成因机制,通过主微量元素、Sr-Nd同位素分析结果,进一步阐明准噶尔洋盆在晚古生代的闭合时限。本次研究包括玄武岩、玄武质安山岩和安山岩三类火山岩,岩体显示低TiO2(0.60%~0.84%)、较高的全碱K2O+Na2O含量(1.18%~8.59%),玄武岩为岛弧拉斑系列,安山岩类的钙碱元素含量高,具有火山弧火山岩特征。中-低87Sr/86Sr(i)(0.703 250~0.704 559)、相对亏损的Nd同位素(+4.8~+6.8)以及tDM2(483~625 Ma)值表明玄武岩、玄武质安山岩和安山岩同为亏损地幔熔融岩浆分异结晶的产物,安山岩为地幔熔融岩浆后期分离结晶形成;微量元素与同位素地球化学示踪暗示玄武岩、玄武质安山岩和安山岩含有洋壳俯冲过程的脱水流体交代上覆地幔楔的消减组分,安山岩在深部岩浆房经历了壳-幔混合作用,受地壳成分的混染程度更大。大离子亲石元素(LILE)Ba、Sr和轻稀土元素、不相容元素(Th、U、K)相对富集,高场强元素(HFSE)Nb、Ta相对亏损,以及Pb、Zr、Hf的富集,说明该区属于与俯冲消减带相关的构造背景;结合本套火山岩高Ba/La(30.14~208.86)值、低TiO2(0.60%~0.84%)值,以及Ce/Nb比(8.71~12.05)、Th/Nb比(0.93~1.74)等,表明准噶尔洋盆于石炭纪沿着大陆板块下部持续俯冲,洋壳板片的俯冲脱水流体交代地幔楔后增生岛弧。该套中-基性火山岩建造佐证了准噶尔洋盆闭合时限为晚石炭世(ca. 305.5±4.4 Ma),结合区域地质资料分析,提出与俯冲带有关的岩浆通过岛弧拼贴增生到大陆地壳上,进一步为准噶尔盆地基底的岛弧拼贴成因提供了新依据。 相似文献
15.
Xi-chen Wang Wei-liang Liu Xi-chong Hu Bin Xia Wei Huang 《International Geology Review》2018,60(10):1267-1289
The Mesozoic Xigaze ophiolite is a key to understanding the tectonic evolution of the Yarlung Zangbo suture zone. Although many studies have been reported, the formation age and petrogenesis of the Xigaze ophiolite remain controversial. In this paper, new geochronological and geochemical data for mafic dikes (diabase, dolerite), lavas, and gabbros of the Xigaze ophiolite are provided to constrain the origin of the Xigaze ophiolite. Combined with previous studies, three new zircon U–Pb ages of samples from two gabbro and one dolerite samples show that the Xigaze ophiolite was produced at two distinct stages of 174–149 Ma and 137–123 Ma. Whole-rock geochemical data indicate that these rocks exhibit N-MORB-like features, but the gabbros are more depleted in trace elements and belong to cumulates. Geochemical characters, combined with their positive εNd(t) values (+3.2 to +9.6), suggest that these samples originated from depleted mantle sources with minor influence of slab-derived fluids. Considering the previous studies on the Yarlung Zangbo suture zone, the Xigaze ophiolite was likely generated in an active continental margin fore-arc basin with a multistage model associated with the northward subduction of the Yarlung Zangbo Neo-Tethys Ocean beneath the Lhasa terrane. The Middle–Late Jurassic ophiolitic massifs (174–149 Ma) were produced as the result of slab rollback and were followed by subsequent slab break-off at ~ 150 Ma. The fore-arc lithosphere may be frozen at ~150–137 Ma, consistent with the termination of the Gangdese arc magmatism during this period. The Early Cretaceous ophiolitic massifs (137–123 Ma) were developed in relation to the reinitiation of the Neo-Tethyan oceanic lithosphere subduction, the retreat of the subduction zone, and the creation of a fore-arc basin with strong hyperextension in a new cycle. 相似文献
16.
The Zedong ophiolite is the largest ophiolite massif east of Dazhuqu in the Yarlung Zangbo Suture Zone in the southern Tibetan Plateau. However, its age, geodynamic setting and relationship to the Xigaze ophiolite remain controversial. New zircon U–Pb ages, whole-rock geochemical and Nd–Pb isotopic data from ophiolitic units provide constraints on the geodynamic and tectonic evolution of the Zedong ophiolite. U–Pb zircon geochronology of dolerite lavas and late gabbro–diabase dikes yield weighted mean ages of 153.9 ± 2.5 Ma and 149.2 ± 5.1 Ma, respectively. Strong positive εNd(t) and positive Δ7/4Pb and Δ8/4Pb values indicate derivation from a highly depleted mantle source with an isotopic composition similar to that of the Indian MORB-type mantle. The geochemistry of ophiolitic lavas and early dikes are analogous to typical island arc tholeiites whereas late dikes are similar to boninites. The geochemistry of these rock types suggests multi-stage partial melting of the mantle and gradually enhanced subduction influences to the mantle source through time. Combined with the MORB-like 162.9 ± 2.8 Ma Luobusha ophiolitic lavas, we suggest that the Luobusha lavas, Zedong lavas and early dikes originated in an infant proto-arc setting whereas late dikes in the Zedong ophiolite originated in a forearc setting. Together, they represent a Neo-Tethyan subduction initiation sequence. The Late Jurassic intra-oceanic proto-arc to forearc setting of the Zedong ophiolite contrasts with the continental margin forearc setting for the Xigaze ophiolite, which suggests a laterally complex geodynamic setting for ophiolites along the Yarlung Zangbo Suture Zone. 相似文献
17.
The Zedang and Luobusa ophiolites are located in the eastern section of the Yalung Zangbo ophiolite belt,and they share similar geological tectonic setting and age.Thus,an understanding of their origins is very important for discussion of the evolution of the Eastern Tethys Ocean.There is no complete ophiolite assemblage in the Zedang ophiolite.The Zedang ophiolite is mainly composed of mantle peridotite and a suite of volcanic rocks as well as siliceous rocks,with some blocks of olivinepyroxenite.The mantle peridotite mainly consists of Cpx-harzburgite,harzburgite,some lherzolite,and some dunite.A suite of volcanic rocks is mainly composed of caic-aikaline pyroclastic rocks and secondly of tholeiitic pillow lavas,basaltic andesites,and some boninitic rocks with a lower TiO2 content (TiO2 < 0.6%).The pyroclastic rocks have a LREE-enriched REE pattern and a LILE-enriched (compared to HFSE) spider diagram,demonstrating an island-arc origin.The tholeiitic volcanic rock has a LREE-depleted REE pattern and a LILE-depleted (compared to HFSE) spider diagram,indicative of an origin from MORB.The boninitic rock was generated from fore-arc extension.The Luobusa ophiolite consists of mantle peridotite and mafic-ultramaflc cumulate units,without dike swarms and volcanic rocks.The mantle peridotite mainly consists of dunite,harzburgite with low-Opx (Opx < 25%),and harzburgite (Opx > 25%),which can be divided into two facies belts.The upper is a dunite-harzburgite (Opx < 25%) belt,containing many dunite lenses and a large-scale chromite deposit with high Cr203; the lower is a harzburgite (Opx >25%) belt with small amounts of dunite and lherzolite.The Luobusa mantle peridotite exhibits a distinctive vertical zonation of partial melting with high melting in the upper unit and low melting in the lower.Many mantle peridotites are highly depleted,with a characteristic U-shaped REE pattern peculiar to fore-arc peridotite.The Luobusa cumulates are composed of wehrlite and olivine-pyroxenite,of the P-P-G ophiolite series.This study indicates that the Luobusa ophiolite was formed in a fore-arc basin environment on the basis of the occurrence of highly depleted mantle peridotite,a high-Cr2O3 chromite deposit,and cumulates of the P-P-G ophiolite series.We conclude that the evolution of the Eastern Tethys Ocean involved three stages:the initial ocean stage (formation of MORB volcanic rock and dikes),the forearc extension stage (formation of high-Cr203 chromite deposits and P-P-G cumulates),and the islandarc stage (formation of caic-alkaline pyroclastic rocks). 相似文献