阿拉善地块早古生代岩浆作用成因及构造意义

阿拉善地块早古生代岩浆作用的成因研究,对理解阿拉善地块与古亚洲洋相互作用过程至关重要。本文在阿拉善地块中部新识别出一中志留世花岗岩体(噶顺花岗岩),其锆石U-Pb年龄为432Ma,以高Sr低Y为特征,属弱过铝质、中钾-高钾钙碱性花岗岩,εHf(t)=-8.8~-19.4,形成于古老下地壳岩石的部分熔融。本文同时总结了阿拉善地块其他晚奥陶世-早泥盆世岩浆岩的成分特征,发现阿拉善地块早古生代岩浆岩在成因上可分为两类:类型I,侵位于晚奥陶世-早中志留世,为典型幔源弧岩浆岩,形成于俯冲流体交代地幔楔的部分熔融;类型II,侵位于中晚志留世-早泥盆世,普遍高Sr低Y,形成于古老中基性地壳岩石的部分熔融。纵观阿拉善地块整个早古生代的岩浆作用,在晚奥陶世-早中志留世→中晚志留世-早泥盆世→中晚泥盆世期间,阿拉善地块的岩浆作用从幔源弧岩浆岩过渡到壳源高Sr低Y型花岗岩再到岩浆作用逐渐消失,反映了阿拉善地块陆缘弧从相对伸展环境向挤压弧的转变。这一岩浆作用演化记录了区域构造作用从典型洋陆俯冲到俯冲作用逐渐减弱(直至停止)或者俯冲角度(从陡俯冲向平俯冲)的转变过程;总体上,阿拉善地块早古生代处于越来越挤压的动力学背景之中。

小兴安岭构造带早侏罗世两期俯冲事件:镁铁质侵入岩的锆石年代学、元素地球化学及Sr-Nd-Li同位素制约

位于小兴安岭构造带北缘的二龙山橄榄辉长岩及星火角闪辉长岩,锆石LA-ICP-MS定年结果分别为201±1Ma和186±1Ma。两者的矿物组成不同,星火角闪辉长岩角闪石含量较高(可达15%)。主微量元素组成显示在岩浆演化过程中二龙山橄榄辉长岩经历了橄榄石和单斜辉石的分离结晶,而星火角闪辉长岩主要经历了橄榄石的分离结晶,此外,两者显著的Sr正异常及一定程度的Eu正异常(1.07~1.38),表明两者在岩浆演化过程中都存在明显的斜长石堆晶作用。原始岩浆计算表明两者都具有弧形微量元素组成,富集大离子亲石元素和轻稀土元素,而亏损高场强元素(Nb和Ta),二龙山橄榄辉长岩属于钙碱性到高钾钙碱性岩浆岩,而星火角闪辉长岩属于钾玄岩系列。两者地幔源区都经历了俯冲沉积物熔流体交代作用的影响。此外,两者具有较为一致的Li同位素组成,同MORB以及岛弧玄武岩的锂同位素组成较为一致,或者略低于MORB,进一步限定俯冲交代物质来源为陆源沉积物。两者具有明显不同的Sr-Nd同位素组成,表明小兴安岭构造带北缘东西侧具有明显的地幔不均一性。位于小兴安岭构造带北缘西侧的186Ma星火角闪辉长岩,同古太平洋板块俯冲后撤导致的弧后伸展拉张有关;而小兴安岭构造带北缘东侧的201Ma二龙山橄榄辉长岩,与位于南部张广才岭构造带东缘的209~202Ma镁铁质岩浆岩带同期,共同揭示牡丹江洋俯冲事件发生的时限为209~201Ma,整体而言牡丹江洋俯冲事件开始的时间南部略早于北部。

张广才岭地块早侏罗世晚期花岗闪长岩及其闪长质包体的岩石成因及构造意义

对松嫩-张广才岭地块早侏罗世晚期北长岗花岗闪长岩及其暗色包体开展了详细的岩石学,地球化学及年代学研究。结果表明,北长岗花岗闪长岩中含有大量闪长质暗色微粒包体,包体具有典型的岩浆结构,并发育针状磷灰石,同时斜长石斑晶从核部到边部显示复杂的成分和结构不平衡。寄主岩与包体均为准铝质,高钾钙碱性或高钾钙碱性-钙碱性过渡岩石,两者具有基本一致的稀土元素及微量元素组成,同时都具有正的εNd(t)和锆石εHf(t)值。主微量元素-SiO2协变图中,包体成分的两端分别向寄主花岗闪长岩及该区时代略早的基性岩延伸,三者具有良好的线性关系。以上特征表明北长岗花岗闪长岩中暗色包体为岩浆混合成因,且其原始岩浆可能为受到俯冲沉积物熔流体交代的软流圈地幔。寄主花岗闪长岩原岩主要为中-新元古代新生基性下地壳,并有少量亏损地幔物质的加入。寄主岩和暗色微粒包体具有基本一致的锆石U-Pb年龄(分别为173±2.0Ma和173±1.5 Ma),显示岩浆混合作用发生在早侏罗世晚期。区域构造演化显示,早侏罗世(~185Ma),张广才岭地块处于古太平洋西-北西向俯冲到亚洲大陆之下形成的弧后伸展环境,北长岗花岗闪长岩及其暗色包体的形成暗示早侏罗世晚期(~173Ma)依然存在幔源岩浆活动,该区仍然处于弧后伸展环境,幔源物质的底侵诱发下地壳部分熔融形成研究区长英质岩浆,同时也说明该区早侏罗世晚期仍然存在地壳增生,且增生方式为垂向增生。

海南岛北部晚新生代玄武岩成分演化及成因讨论

板内玄武岩通常具有复杂的成分组成和成因过程。海南岛北部(简称“琼北”)自渐新世始逐渐发育了大量板内玄武岩,岩性跨度大,从石英拉斑玄武岩到橄榄拉斑玄武岩,再到碱性橄榄玄武岩和碧玄岩均有分布。对琼北晚新生代玄武岩虽已开展了广泛的研究,但“琼北晚新生代玄武岩的成分随时间演化规律”这一问题却未引起足够的关注。本文从晚更新世道堂组橄榄玄武岩入手,对其开展了细致的岩石学、矿物学和主微量及Sr-Nd-Pb同位素地球化学的研究;并结合文献中琼北其他时代(组)玄武岩的数据,阐述了琼北晚新生代玄武岩成分随时间演化的规律并对其成因进行了探讨。研究发现,自中—上新世到更新世再到全新世,琼北晚新生代玄武岩呈现从碱性玄武岩过渡到拉斑玄武岩再突变到碱性—强碱性系列的演化规律;中—上新世到更新世这一时期的碱性玄武岩和拉斑玄武岩可能形成于石榴子石二辉橄榄岩由低到高程度的部分熔融作用,而全新世碱性岩则更可能形成于石榴子石辉石岩的部分熔融。琼北晚新生代玄武岩的Sr-Nd-Pb同位素组成揭示其源区地幔以PREMA端元为主,但经历了来自古老陆壳的沉积物不同程度的改造作用。采用“海南地幔柱”模型可以较好地解释琼北晚新生代玄武岩的复杂组成和成因。

海南岛晚新生代石山组橄榄玄武岩的地幔源区组成及动力学机制

南海北部边缘新生代玄武岩广泛分布,分布于海南岛北部的全新世早期石山组玄武岩,岩石组成为碱性橄榄玄武岩,其中可见较大颗粒的橄榄石斑晶,橄榄石斑晶具有较高的Fo值(82.8~83.5)和Ni含量(0.14%~0.20%)。橄榄玄武岩的微量元素及同位素组成与洋岛玄武岩(OIB)高度吻合,富集大离子亲石元素Rb、Ba和轻稀土元素,同时富集高场强元素Nb、Ta、Zr和Hf。矿物组成及主微量元素特征指示其源区为含石榴子石辉石岩源区,经历了较低程度的部分熔融(约5%)。此外,石山组橄榄玄武岩具有基本一致的Sr-Nd-Pb同位素组成,表明岩浆在上升过程中没有明显的地壳物质的混染,但是相比正常洋中脊玄武岩(MORB),石山组橄榄玄武岩具有较高的^(87)Sr/^(86)Sr比值,较低的εNd(t)值,以及较高的^(207)Pb/^(204)Pb(15.639~15.643)和^(208)Pb/^(204)Pb(38.977~38.996)比值,说明其源区为亏损地幔(DM)和富集地幔端元(EMII)的混合。结合地球物理学证据,我们认为亏损地幔来源于软流圈,而EMII端元为含再循环古洋壳及俯冲沉积物的地幔柱,随着海南地幔柱上升,再循环物质熔融并与周围软流圈地幔橄榄岩反应形成含石榴子石辉石岩,随着地幔柱的不断上升,辉石岩首先发生部分熔融,形成的岩浆经历了橄榄石和微弱单斜辉石的分离结晶作用后形成了石山组橄榄玄武岩。华南新生代玄武岩同石山组橄榄玄武岩具有相似的地球化学特征,反映二者具有相同的物质端元组成,但两者岩浆演化上升的动力学机制不同,同时不同端元混合的比例及部分熔融程度也有差异。

小兴安岭构造带早白垩世最晚期镁铁质侵入岩的岩石成因及地质意义

丰丽镁铁质侵入岩位于小兴安岭构造带北缘,其岩石组成主要为角闪辉长岩和辉长岩。其中角闪辉长岩中含有较大的角闪石斑晶,并可见单斜辉石和斜长石包含其中。SHRIMP锆石U-Pb定年结果显示岩体侵位年代为107±1.0Ma。丰丽岩体具有基本一致的(87Sr/86Sr)i(0.7065)和εNd(t)(-0.17~0.14)组成,表明岩浆上升过程中没有受到地壳物质的混染,且同早中生代镁铁质岩浆岩相比,丰丽岩体的Sr-Nd同位素组成较为富集,可能与古亚洲洋和古太平洋多期次俯冲交代导致大离子亲石元素和轻稀土元素的富集累积有关。全岩主微量元素组成揭示岩浆来源于亏损的岩石圈地幔,其源区物质组成为尖晶石二辉橄榄岩,岩浆经历了较低程度的部分熔融(~3%),岩浆演化过程中经历了明显的橄榄石、单斜辉石、斜方辉石及钛铁矿物的分离结晶。锆石氧同位素组成δ^(18)O值变化于5.0‰~6.6‰之间,平均值为5.8‰,略高于典型地幔锆石的δ^(18)O值,暗示岩浆源区曾受到洋壳上部俯冲沉积物熔流体交代作用影响,同时角闪石矿物的结晶说明原始岩浆含水量较高,也证明源区经历过丰富的流体交代作用的影响。早白垩世最晚期(110~100Ma),东北地区岩浆作用的空间分布范围集中在最东部地区,岩性上主要为碱性岩、双峰式火山岩及少量的镁铁质岩浆岩,说明此时东北地区处于古太平洋后撤导致的陆内伸展拉张环境中,岩石圈地幔发生减压部分熔融形成了研究区镁铁质岩浆岩。

雅鲁藏布江缝合带西段东波地幔橄榄岩体钻孔岩心研究

东波地幔橄榄岩是雅鲁藏布江缝合带内代表性超镁铁岩体,位于缝合带西段,面积超过400km2。为查明岩体成因,在岩体中实施了一口千米深的科学钻探(DSD-1)。除上部有约23m厚的第四系堆积物外,钻孔均钻进在地幔橄榄岩中,孔深1002.06m,岩心采取率96.62%。岩心编录结合显微镜下鉴定将岩心划分出44个岩性单元层,并进一步归并为上、下两套岩性:上部(23.1~340.17m)为含单辉方辉橄榄岩(斜方辉石含量为15~20%,单斜辉石含量不足5%);下部(340.17~1002.06m)为方辉橄榄岩(斜方辉石含量为10%~15%,几乎不含单斜辉石),其中发育薄层状纯橄岩和辉石岩以及辉绿岩脉。矿物学及全岩地球化学研究揭示:①东波地幔橄榄岩以方辉橄榄岩为主,其次为含单辉方辉橄榄岩,它们均具有亏损的全岩地球化学及矿物成分组成,指示它们为经历过中高程度部分熔融后的地幔残余岩石;经历过富水流体(熔体)交代作用,表现为角闪石呈柱状交代斜方辉石;②纯橄岩和辉石岩以透镜状或薄层状脉体发育于方辉橄榄岩中,具有岩浆成因的矿物组成,见交代矿物角闪石,指示它们可能为交代成因;③辉绿岩脉兼具N-MORB和弧玄武岩的化学属性,以低SiO2、高MgO和高Al2O3含量为特征,具有与Western Lau Basin玄武岩一致的REE配分型式,形成于较为成熟的弧后盆地环境。东波地幔橄榄岩(及其中的纯橄岩、辉石岩和辉绿岩脉)在成因上与俯冲带关系密切,都受到了与俯冲带相关地质作用的影响。

古太平洋板片晚二叠-早三叠世俯冲后撤:来自海南岛弧岩浆作用的制约

海南岛大规模二叠-三叠纪侵入岩的形成是与古特提斯洋有关,还是与古太平洋俯冲闭合有关还存在巨大争议。本文对琼中金波两处辉绿岩脉及其围岩花岗岩的研究显示,露头1辉绿岩脉的锆石U-Pb年龄为245.4±3.8Ma,TiO_(2)含量(1.07%~1.18%)低,而MgO(8.60%~9.41%)和Mg^(#)值(62.31~65.02)较高,为钙碱性系列,球粒陨石和原始地幔标准化配分曲线中具有明显的Eu、Nb、Ta、Ti和Ba负异常,以及显著Th、U、Zr、Rb和Pb等正异常,(^(87)Sr/^(86)Sr)_(i)=0.707138~0.712797,(^(143) Nd/^(144)Nd)_(i)=0.511884~0.511965,ε_(Nd)(t)值为-7.01~-8.58,指示其形成于大陆岛弧环境。相比之下,露头2辉绿岩锆石U-Pb年龄为242.8±3.1Ma,但其TiO_(2)(2.65%~3.06%)含量较高,而MgO(4.24%~5.39%)和Mg^(#)值(40.09~45.86)较低,具有Eu、Rb、Pb、Nb、Ta和Ti弱正异常和Th负异常,(^(87)Sr/^(86)Sr)_(i)=0.690244~0.717031,(^(143) Nd/^(144)Nd)_(i)=0.512886~0.512915,ε_(Nd)(t)值为+6.41~+7.93,具有板内玄武岩的特征,指示其形成于板内裂解环境。辉绿岩脉围岩二长花岗岩的锆石U-Pb年龄为255.3±3.0Ma和255.7±3.2Ma,含少量角闪石和黑云母,具有较高的SiO_(2)(71.62%~73.72%)、Na_(2)O+K_(2)O(6.60%~9.17%)和Al_(2)O_(3)(平均14.88%)含量,A/CNK值(0.97~1.03)较低,亏损Nb、Ta、Ti、Sr和Ba,富集Rb、Th、U和Pb,为高分异I型岛弧花岗岩。总的来看,二长花岗岩和辉绿岩形成于大陆岛弧挤压向伸展过渡的构造环境。对比二叠-三叠纪侵入岩体的走向、碰撞前-同碰撞-碰撞后岩浆岩的时代以及榴辉岩的变质年龄等,发现海南岛侵入岩与哀牢山-松马造山带明显不同,而与日本和朝鲜半岛的岛弧岩浆岩类似,由此我们认为海南岛大规模晚二叠-早三叠世岩浆岩为古太平洋板片向欧亚板块俯冲后撤的产物,后撤过程受到古特提斯俯冲板片的影响。

碱性岩中富钛钙铁榴石的成因及成岩成矿意义:以河北矾山超镁铁岩-正长岩杂岩体中的石榴石为例

富钛钙铁榴石是硅不饱和碱性火成岩中的特征矿物,其Ti含量和Ti进入石榴石的方式可直接反映岩浆体系的硅饱和度和氧逸度。河北矾山超镁铁岩-正长岩杂岩体是华北克拉通北缘东西向展布三叠纪碱性岩带的重要岩体之一,其岩石中发育三种类型的富钛钙铁榴石:类型Ⅰ发育于岩体外带的石榴石辉石正长岩中,与辉石、黑云母呈岩浆共生关系,端元组成为Adr_(25-65)Mmt_(15-37)Slo_(8-28)Grs_(10-14),以高TiO_(2)含量(6.08%~18.61%)、较低的SiO_(2)含量(25.46%~33.26%)为特征,为原生岩浆成因;类型Ⅱ见于各类岩石,呈细粒他形充填于其他矿物颗粒之间,端元组成为Adr_(57-69)Mmt_(5-19)Slo_(0-6)Grs_(19-27),以高Al_(2)O_(3)含量(3.95%~5.56%)为特征,为岩浆演化后期熔体富Al_(2)O_(3)时结晶而成;类型Ⅲ亦见于各类岩石,主要呈细粒他形或细碎状发育于其他矿物内,端元组成为Adr_(68-79)Mmt_(8-14)Slo_(0-5)Grs_(6-14),以低的Al_(2)O_(3)含量(1.18%~2.89%)和较高的FeO含量(21.65%~24.62%)为特征,为岩浆期后热液成因。在矾山杂岩体的富钛钙铁榴石中,Ti主要以Si→Ti^(4+)和2Fe^(3+)→Ti^(4+)+Fe^(2+)/Mg替代方式进入到晶体结构中,反映了矾山杂岩体的母岩浆体系为二氧化硅不饱和的碱性岩浆,并具有较高的氧逸度。受石榴石的主量元素组成和相应的晶体结构控制,在微量元素组成上,矾山杂岩体中的富钛钙铁榴石富集轻稀土或中稀土、亏损重稀土,大离子亲石元素(Rb、Ba、Pb和Sr)含量较低或极低,而高场强元素(如Th、U、Nb、Ta、Zr和Hf等)含量普遍较高。本文对石榴石的成因研究结果支持矾山杂岩体不同类型的岩石形成于封闭体系下同一母岩浆系统充分的结晶-分异和堆晶作用;此演化模式可以较好地解释矾山杂岩体的同心环状特征和韵律层状结构,以及磁铁矿和磷矿的成因。

西藏仲巴地体中433Ma伸展热事件：波库二云母花岗岩锆石年代学、地球化学和Hf同位素制约

喜马拉雅造山带中发育多期次淡色花岗岩,其成因与构造转换密切相关。波库二云母花岗岩位于仲巴地体西段,锆石U-Pb年龄为433.4±2.0Ma,εHf(t)=-11.18^-8.75。全岩地球化学显示具有较高的SiO2(72.38%~73.10%)、Al2O3(15.14%~15.38%)、CaO(1.54%~1.77%)、Sr(141×10^-6~174×10^-6)、Ba(386×10^-6~574×10^-6)含量和δEu值(平均0.8),以及较低K2O/Na2O(0.87~1.11)和Rb/Sr(0.86~1.09)比值,A/CNK=1.64~1.77,随着Ba含量的增加,Rb/Sr比值保持不变。这些特征表明波库二云母花岗岩为变泥质岩发生水致白云母部分熔融的产物,与原特提斯洋向冈瓦纳大陆北缘俯冲后仲巴地体-特提斯喜马拉雅地体与冈瓦纳大陆亲缘性的陆块发生碰撞后板片断离伸展环境下的岩浆热事件相关,与特提斯喜马拉雅429Ma吉隆白云母脱水部分熔融形成的淡色花岗岩的成因不同表明它们发生部分熔融作用的物理化学条件不同,亦指示仲巴地体与特提斯喜马拉雅地体在早古生代可能具有不同的构造演化环境。

南海北部陆缘新生代玄武岩地球化学特征及成因

南海盆地及周缘地区新生代玄武岩对揭示南海盆地的演化历史至关重要,然而这些玄武岩的成因还存在争议。本文研究了位于南海北部陆缘的海南岛临高县多文组玄武岩岩石地球化学和矿物地球化学特征,并探讨其成因和构造背景。多文组玄武岩主要由橄榄石、单斜辉石、斜长石、斜方辉石、铬尖晶石和铁钛氧化物等组成。橄榄石Fo值变化于55.5~71.1之间,Ni的含量较低,Fe/Mn比值较高。铬尖晶石Cr^(#)值为74.1~82.7,Mg^(#)值为45.5~63.8,Ti的含量较高。斜方辉石Mg^(#)值为63.9~79.6,单斜辉石为66.0~80.6。单斜辉石稀土配分曲线富集MREE,亏损LREE和HREE,呈拱形分布。斜长石以中-拉长石为主(Ab_(36.56~52.78)),富集LREE、Ba、Sr和Eu。铁钛氧化物的TiO_(2)含量为50.19%~51.46%。多文组玄武岩原始岩浆的主量和微量元素组成与夏威夷、峨眉山、塔里木等玄武岩组成一致,地幔源区包含了辉石岩的成分,而且其地幔潜在温度(>1400℃)和氧逸度(ΔNNO)要高于大洋中脊玄武岩(N-MORB),表明多文组玄武岩的形成与海南地幔柱活动有关。由于海南地幔柱形成时代明显晚于南海盆地的扩张时代,认为南海地幔柱是南海盆地伸展的被动响应。

U-Pb Zircon Age, Geochemical, and Sr-Nd-Pb Isotopic Constraints on the Age and Origin of Mafic Dykes from Eastern Shandong Province, Eastern China

U-Pb zircon age, geochemical, and Sr-Nd-Pb isotopic data of mafic dykes from eastern Shandong Province, eastern China is reported herein. Laser ablation inductively coupled plasma mass spectrometry （LA-ICP-MS） U-Pb zircon analyses of two samples from the investigated mafic dykes yield consistent ages ranging from 121.9 Ma ± 0.47 Ma to 122.9 Ma ± 0.61 Ma. The mafic dykes are characterized by high （87Sr/86Sr） i ranging from 0.7087 to 0.7089, low εNd（t） values ranging from -16.9 to -17.8, 206Pb/204Pb = 17.15 to 17.17, 207Pb/204Pb = 15.45 to 15.47, and 208Pb/204Pb = 37.59 to 37.68. Results from the current study suggest that the mafic dykes are derived from partial melting of ancient lithospheric mantle that was variably hybridized by melts derived from foundered lower crustal eclogite. The mafic dykes may have been generated through subsequent insignificant crystal fractionation and very minor crustal contamination during magma ascent. Combined with previous studies, the current findings provide new evidence that the intense lithospheric thinning beneath the eastern Shandong Province of eastern China occurred at ~120 Ma, and that this condition was caused by the removal of the lower lithosphere （mantle and lower crust）.

Petrological and Re-Os Isotopic Constraints on the Origin and Tectonic Setting of the Cuobuzha Peridotite, Yarlung Zangbo Suture Zone, SW Tibet, China

The Yarlung Zangbo Suture Zone（YZSZ）in southern Tibet includes the remnants of Neotethyan oceanic lithosphere and marks a major suture between the Indian Plate to the south and the Lhasa Terrane of Tibet to the north（Dupuis et al.,2005;Yang et al.,2011）.In the western part of the YZSZ,the Northern and the Southern sub-belts form two sub-parallel zones of mafic–ultramaficrockassemblageswithoverlapping crystallization ages（Xiong et al.,2011;Hebért et al.,2012;Liu et al.,2015）.The upper mantle section of the Cuobuzha ophiolite in the northern sub-belt of the Yarlung–Zangbo Suture Zone（YZSZ）in SW Tibet comprises mainly clinopyroxene（cpx）–rich and depleted harzburgites.Spinels in the cpx-harzburgites show lower Cr#values（12.6–15.1）than the spinels in the harzburgites（26.1–34.5）,and the cpx-harzburgites display higher heavy rare earth element concentrations than the depleted harzburgites.The harzburgites have subchondritic Os isotopic compositions（0.11624–0.11699）,whereas the cpx-harzburgites have suprachondritic 187Os/188Os ratios（0.12831–0.13125）with higher Re concentrations（0.380-0.575 ppb）.The cpx-harzburgites plot in a Re vs.Al2O3 diagram as a result of subsequent addition of Re following the last partial melting event that occurred during mid-ocean ridge melt evolution processes（Uysal et al.,2015）.Although these geochemical and isotopic signatures suggest that both peridotite types in the ophiolite represent mid-ocean ridge type upper mantle units,their melt evolution trends reflect different mantle processes.The cpx-harzburgites formed from low-degree partial melting（;%）of a primitive mantle source,and they weresubsequently modified by melt–rock interactions in a mid-ocean ridge environment.The depleted harzburgites,on the other hand,were produced by re-melting of the cpx-harzburgites,which later interacted with MORB-or island arc tholeiite（IAT）-like melts（Fig.1）possibly in a trench-distal backarc spreading center.Our new isotopic and geochemical data from the Cuobuzha peridotites confirm that the Neotethyan upper mantle had highly heterogeneous Os isotopic compositions as a result of multiple melt production and melt extraction events during its seafloor spreading evolution.

Early Devonian Ultrapotassic Magmatism in the North China Craton: Geochemical and Isotopic Evidence for Subcontinental Lithospheric Mantle Metasomatism by Subducted Sediment–Derived Fluid

The North China Craton(NCC) represents one of the oldest and largest cratons in the earth with a nearly complete record of Precambrian history. In the northern part of the NCC, the earliest phase of alkaline magmatism occurred in discrete pulses in the Early and Middle Devonian;whereas the next episode of alkaline magmatism took place in the early Mesozoic. The Gucheng pluton is exposed in the northern part of the NCC and forms a composite intrusion, consisting of K-feldspar–bearing clinopyroxenite, clinopyroxene–bearing syenite and alkali-feldspar syenite. Mineral phases in these lithologies include clinopyroxene(Wo43-48En19-35Fs18-38), sanidine(An0 Ab3-11Or89-97), and subordinate titanite, andradite and Na-feldspar. These rocks show homogeneous Sr but variable Nd isotopic compositions, and have relatively high zircon in-situ oxygen isotopes(δ18O=5.2–6.7). The Gucheng plutonic rocks formed through fractional crystallization and accumulation from ultrapotassic magmas, which were originated from partial melting of metasomatic vein systems in the subcontinental lithospheric mantle of the NCC. These vein networks developed as a result of the reactions of fluids derived from subducted pelitic sediments on the downgoing Palaeo-Asian ocean floor with the enriched, subcontinental lithospheric mantle peridotites. SHRIMP U-Pb zircon dating has revealed a crystallization age of 415 Ma for the timing of the emplacement of the Gucheng pluton that marks the early stages of alkaline magmatism associated with the Andean-type continental margin evolution along the northern edge of the NCC facing the Palaeo-Asian Ocean.

Kalaymyo Peridotite Massif in the Indo-Myanmar Ranges(Western Myanmar): Its Mineralogy and Petrology

Mesozoic ophiolites crop out discontinuously in the Indo-Myanmar Ranges in NE India and Myanmar,and represent the remnants of the Neotethyan oceanic lithosphere(Sengupta et al.,1990;Mitchell,1993).These ophiolites in the Indo-Myanmar Ranges are the southern continuation of the Neotethyan ophiolites occurring along the Yarlung Zangbo Suture Zone(YZSZ)in southern Tibet farther northwest(Mitchell,1993;Fareeduddin and Dilek,2015),as indicated by their coeval crystallization ages and geochemical compositions(Yang et al.,2012;Liu et al.,2016).The Kalaymyo ophiolite is located in the central part of the eastern Indo-Myanmar Ranges(Fig.1).composition of these ophiolites from the central Tibetan Plateau(CTP)is dominated by MORBs and minor OIBs and a distinct lack of IATs and BONs,which is inconsistent with most ophiolites worldwide(Robinson and Zhou,2008;Zhang et al.,2008).But the generation and tectonic nature of these ophiolites are still controversial.*The Kalaymyo peridotites consist mainly of harzburgites,which show typical porphyroclastic or coarse-grained equigranular textures.They are composed ofolivine(Fo=89.8–90.5),orthopyroxene(En86-91Wo1-4Fs8-10;Mg#=89.6–91.9),clinopyroxene(En46-49Wo47-50Fs3-5;Mg#=90.9–93.6)and spinel(Mg#=67.1–78.9;Cr#=13.5–31.5),and have relatively homogeneous whole-rock compositions with Mg#s of90.1–90.8 and Si O2(41.5–43.65 wt.%),Al2O3(1.66–2.66wt.%)and Ca O(1.45–2.67 wt.%)contents.TheydisplayLightRareEarthElement(LREE)-depleted chondrite-normalized REE patterns with(La/Yb)CN=0.04–0.21 and(Gd/Yb)CN=0.40–0.84,and show a slight enrichment from Pr to La with(La/Pr)CN in the range of 0.98–2.36.The Kalaymyo peridotites are characterized by Pd-enriched chondrite-normalized PGE patterns with superchondritic(Pd/Ir)CN ratios(1.15–2.36).Their calculated oxygen fugacities range between QFM–0.57 and QFM+0.90.These mineralogical and geochemical features collectively suggest that the Kalaymyo peridotites represent residual upper mantle rocks after low to moderate degrees(5–15%)of partial melting at a mid-ocean-ridge(MOR)environment.The observed enrichment in LREE and Pd was a result of their reactions with enriched MORB-like melts,percolating through these already depleted,residual peridotites.The Kalaymyo and other ophiolites in the Indo-Myanmar Ranges hence represent mid-ocean ridge(MOR)–type Tethyan oceanic lithosphere derived from a downgoing plate and accreted into a westward migrating subduction–accretion system along the eastern margin of India.

Geochronology and Genetic Model for Early Cretaceous Volcanic Rocks from the Southern Qiangtang Terrane,Northern Tibet,China: Constraints from U-Pb Zircon Dating, Whole-Rock Geochemical and Sr-Nd Isotopic Data

Post-collisional volcanic rocks of Mesozoic age occur in the regions adjacent to Gerze, part of the southern Qiangtang Terrane of northern Tibet, China. Geochronological, geochemical, and wholerock Sr-Nd isotopic analyses were performed on the volcanic rocks to better characterize their emplacement age and models for their origin. Laser ablation-inductively coupled plasma-mass spectrometry(LA-ICP-MS) U-Pb zircon analyses yielded consistent ages ranging from 123.1±0.94 Ma to 124.5±0.89 Ma for six volcanic rocks from the study area. The intermediate volcanic rocks belong to the alkaline and sub-alkaline magma series in terms of K2 O+Na2 O contents(5.9%–9.0%), and to the shoshonitic and calc-alkaline series on the basis of their high K2 O contents(1.4%–3.3%). The Gerze volcanic rocks are characterized by the enrichment of light rare earth elements [(La/Yb)N=34.9–49.5] and large–ion lithophile elements(e.g., Rb, Ba, Th, U, K, Pb, and Sr), slightly negative Eu anomalies(Eu/Eu*=0.19–0.24), and negative anomalies in high field strength elements(e.g., Nb, Ta, Hf and Ti), relative to primitive mantle. The samples show slightly elevated(87 Sr/86 Sr)i values that range from 0.7049 to 0.7057, and low εNd(t) values from-0.89 to-2.89. These results suggest that the volcanic rocks studied derived from a compositionally heterogeneous mantle source and that their parent magmas were basaltic. The more mafic, parental magmas to the Gerze volcanic rocks likely underwent fractional crystallization of clinopyroxene, hornblende, biotite, and potassium feldspar, during ascent, with little to no crustal contamination, prior to their eruption/emplacement. While these volcanic rocks exhibit geochemical signatures typical of magmas formed in a destructive plate-margin setting, it is plausible that their mantle source might also have acquired such characteristics in an earlier episode of subduction.

Zircon U-Pb Age,Geochemical,and Sr-Nd-Pb-Hf Isotopic Constraints on the Time Frame and Origin of Early Cretaceous Mafic Dykes in the Wuling Mountain Gravity Lineament,South China

In view of the importance of mafic dyke swarms and their contribution to current scientific problems relating to South China,herein,we present the findings of studies on twenty–five representative mafic dykes cropping out in Hunan Province and Guangxi Zhuang Autonomous Region,within the southern Wuling Mountain gravity lineament,China.These results include new zircon LA-ICP-MS U-Pb age,whole rock geochemical,Sr-Nd-Pb isotopic,and zircon Hf isotopic data for these dykes.The dykes formed between 131.5±1.2 and 121.6±1.1 Ma,and have typical doleritic textures.They fall into the alkaline and shoshonitic series,are enriched in light rare earth elements(LREE),some large ion lithophile elements(LILE;e.g.,Rb,Ba,and Sr),Th,U,and Pb,and are depleted in Nb,Ta,Hf,and Ti.Moreover,the dolerites have high initial 87 Sr/86 Sr ratios(0.7055–0.7057),negativeεNd(t)and zirconεHf(t)values(-14.8 to-11.9,-30.4 to-14.9),and relatively constant initial Pb isotopic ratios(that are EM1-like,16.77–16.94,15.43–15.47,and 36.84–36.92 for 206 Pb/204 Pb,207 Pb/204 Pb,and 208 Pb/204 Pb,respectively).These results indicate that the dykes were likely derived from magma generated through low-degree partial melting(1.0%–10%)of an EM1-like garnet–lherzolite mantle source.The parental magmas fractionated olivine,clinopyroxene,plagioclase,and Ti-bearing phases with negligible crustal contamination,during ascent and dyke emplacement.Several possible models have been proposed to explain the origin of Mesozoic magmatism along the Wuling Mountain gravity lineament.Herein we propose a reasonable model for the origin of these mafic dykes,involving the collision between the paleo-Pacific Plate and South China,which led to subsequent lithospheric extension and asthenosphere upwelling,resulting in partial melting the underlying mantle lithosphere in the Early Cretaceous,to form the parental magmas to the WMGL mafic dykes,as studied.

Geochemistry and Geochronology of OIB-type Early Jurassic Magmatism in the Zhangguangcai Range, NE China, as a Result of Continental Back-arc Extension

The Zhangguangcai Range in the Xing’an(Hinggan) Mongolian Orogenic Belt, NE China, contains Early Jurassic(c. 188 Ma) Dabaizigou(DBZG) porphyritic dolerite. Compared with other island-arc mafic rocks, the DBZG dolerite is characterized by high trace-element contents, relatively weak Nb and Ta enrichments, and no Zr, Hf or Ti depletions, similar to OIB-type rocks. Analysed rocks have(87Sr/86Sr)i ratios of 0.7033–0.7044, relatively uniform positive εNd(t) values of 2.3–3.2 and positive εHf(t) values of 8.5–17.1. Trace-element and isotopic modelling indicates that the DBZG mafic rocks were generated by partial melting of asthenospheric mantle under garnet-to spinel-facies conditions. The occurrence of OIB-like mafic intrusion suggests significant upwelling of the asthenosphere in response to lithospheric attenuation caused by continental rifting. These processes occurred in an incipient continental back-arc environment in the upper plate of a palaeo-Pacific slab subducting W–NW beneath East Asia.

Ocean-continent Transition to Suprasubduction Zone Origin of the Western Yarlung Zangbo Ophiolites in SW Tibet, China: Multi-stage, Transient Evolution of the Neotethyan Oceanic Lithosphere

The ophiolites that crop out discontinuously along the;000 km Yarlung Zangbo Suture zone（YZSZ）between the Nanga Parbat and Namche Barwa syntaxes in southern Tibet represent the remnants of Neotethyan oceanic lithosphere（Fig.1a）.We have investigated the internal structure and the geochemical makeup of mafic-ultramafic rock assemblages that are exposed in the westernmost segment of the YZSZ where the suture zone architecture displays two distinct sub-belts of ophiolitic and mélange units separated by a continental Zhongba terrane（Fig.1b）.These two sub-belts include the Daba–Xiugugabu in the south（Southern sub-belt,SSB）and the Dajiweng–Saga in the north（Northern sub-belt,NSB）.We present new structural,geochemical,geochronological data from upper mantle peridotites and mafic dike intrusions occurring in these two sub-belts and discuss their tectonomagmatic origin.In-situ analysis of zircon grains obtained from mafic dikes within the Baer,Cuobuzha and Jianabeng massifs in the NSB,and within the Dongbo,Purang,Xiugugabu,Zhaga and Zhongba in the SSB have yielded crystallization ages ranging between130 and 122 Ma.Dike rocks in both sub-belts show N-MORB REE patterns and negative Nb,Ta and Ti anomalies,reminiscent of those documented from SSZ ophiolites.*Harzburgitic host rocks of the mafic dike intrusionsmainly display geochemical compositions of abyssal peridotites（Fig.2）,with the exception of the Dajiweng harzburgites,which show the geochemical signatures of forearc peridotites（Lian et al.,2016）.Extrusive rocks that are spatially associated with these peridotite massifs in both sub-belts also have varying compositional and geochemical features.Tithonian to Valanginian（150–135 Ma）basaltic rocks in the Dongbo massif have OIB-like geochemistry and 138 Ma basaltic lavas in the Purang massif have EMORB-like geochemistry（Liu et al.,2015）.Tuffaceous rocks in the Dajiweng massif are140 Ma in age and show OIB-like geochemistry.We interpret these age and geochemical data to reflect a rifted continental margin origin of the extrusive rock units in both sub-belts.These data and structural observations show that the western Yarluang Zangbo ophiolites represent fragments of an Ocean-Continent Transition（OCT）peridotites altered by fluids in an initial supersubduction setting.We infer that mafic-ultramafic rock assemblages exposed in the SSB and NSB initially formed in an ocean–continent transition zone（OCTZ）during the late Jurassic,and that they were subsequently emplaced in the forearc setting of an intraoceanic subduction zone within a Neotethyan seaway during 130 to 122 Ma.The NSB and SSB are hence part of a single,S-directed nappe sheet derived from a Neotethyan seaway located north of the Zhongba terrane.

Tectonic Evolution of Neotethys Ocean: Evidence of Ophiolites and Ocean Plate Stratigraphy from the Northern and Southern belts in the Western Yarlung Zangbo Suture Zone, Tibet

The Yarlung Zangbo suture zone(YZSZ)separates Indian plate and its northern passive margin units to the south from Eurasian plate and its active continental margin units of Xigaze forearc basin and Gangdese batholith to the north(Xu et al.,2015;Yang et al.,2015).The western YZSZ in southern Tibet is divided by the Zhongba terrane into the northern belt(NB)and southern belt(SB).Ophiolites in the NB are dismembered as ophiolitic mélanges.Peridotite,cumulated gabbro,ocean plate stratigraphy(OPS)of seamount remnants and pelagichemipelagic sequence as blocks in serpentinite matrix are mainly observed,from west to east,in Dajiweng,Baer,Kazhan,Cuobuzha,Zhalai,Gongzhu.Ophiolites in the SB are absent ophiolitic units of sheeted dikes and MORB-like pillow lavas,occur as much larger peridotite massifs(i.e.,Dongbo,400 km^2;Purang,650 km^2;Xiugugabu,700 km^2;Dangqiong,300 km^2)which are intruded by mafic dike swarms and overlain by volcanic sedimentary OPS(Liu et al.,2018).We propose that the SB mafic–ultramafic rocks and volcanic sedimentary OPS represent fragments of an early Cretaceous continental margin ophiolite whose magmatic evolution was influenced by 140–137 Ma plume magmatism(Liu et al.,2015;Zheng et al.,2019).Relics of Late Paleocene to very Early Eocene deep-marine basin were developed in Saga and Gyirong(Ding,2003;Li et al.,2018).In contract,the NB ophiolitic mélanges report a travel log of an oceanic plate ranging from Middle Triassic to Early Cretaceous.