试论“塔里木-扬子古大陆”再造

扬子古板块在地史演化中,是与塔里木板块靠近还是与华北古板块相近,这是中国大陆再造中长期争论的问题。在前人有限资料基础上,从岩石学、古气候学和古生物学等方面,论证扬子与塔里木古板块内部地质特征的可比性,从构造解析板块边缘造山带的岩石学记录,追踪扬子与塔里木古板块地史演化中的相关性,得出从新元古代至二叠纪扬子古板块多与塔里木古板块靠近,成为一个大陆,我们暂命名为“塔里木-扬子古大陆”。后经“峨眉地幔柱”的作用和“峨眉地裂运动”的拉张,古大陆解体,二板块分离,扬子古板块向东漂移到现今位置。二板块会聚和离散的演化模式若能成立,则涉及到中国一些基础地质科学的重新认识,也对预测大型矿产提供一点新思路。     

浅变质岩在示踪大别—苏鲁造山带大陆板块俯冲与折返过程中的意义

中国大别-苏鲁造山带为大陆板块俯冲形成的碰撞造山带,该带北缘和内部产有原岩时代为新元古代-晚古生代的浅变质岩。这些浅变质岩对应于扬子板块北缘前寒武变质基底和扬子板块北缘古生代大陆架沉积物,形成过程于印支期扬子板块向北俯冲过程中的刮削作用密切相关,与大洋板块俯冲过程中刮削形成的加积楔具有类似的动力学过程。对大别-苏鲁造山带浅变质岩的深入研究,不仅有助于揭示大陆板块俯冲过程中高压-超高压岩石形成与折返过程,而且确定了扬子板块与华北板块之间的缝合线位置位于大别造山带北淮阳带的北部和苏鲁造山带的五莲-蓬莱群的北侧。     

扬子板块西缘早元古代俯冲体系的地球化学证据—有关变基性岩的微量元素地球化学研究

本文通过对云南早元古代哀牢山群、底巴都组与大红山群的地质地球化学研究，从地球化学角度证明早元古代扬子板块西缘存在板块运动，前特提斯域的元古大洋板块在其东北方向的俯冲作用中，与古扬子板块发生碰撞而在俯冲带大陆边缘弧与弧后盆地分别形成哀牢山群、底巴都组与大红山群的基性火山岩。     

岩石圈—软流圈物质循环促进大陆增生的新方式

大陆动力学研究地球内能量和物质的运动和伴随的信息传播,上地幔中的软流圈是地球内部的物质运动的关键部位之一。由于观测的技术方法少,人类对软流圈内部的地质作用过程所知甚少。在青藏高原,过去地震波三维层析成像的分辨率不高,难以对地壳上地幔构造进行准确的定位。我们收集和整理了地方地震台的数字化观测数据,使地震体波三维层析成像的准确度大大提高,为解决软流圈的地质构造准确成像提供了新的可能性。根据地震体波三维层析的成像结果,在古特提斯洋和特提斯洋俯冲板块前沿的软流圈底部410 km间断面上方,存在反映古大洋俯冲板块的高速体,它们在青藏高原、苏鲁和伊朗都有出现。清晰和稳定的高波速异常的位置表明,特提斯洋俯冲板块现在已经拆沉在软流圈的底部,古特提斯洋俯冲板块也可能曾经拆沉在软流圈的底部。对比青藏高原和苏鲁的地壳上地幔波速结构推测,拆沉造成软流圈中的轻元素物质上涌,进入大陆岩石圈,造成岩浆活动。上涌还使碰撞造山带地壳厚度减小,而岩石圈厚度增加。大约100 Ma后,俯冲下去的大洋残块会被软流圈物质磨蚀交代,使岩石圈厚度增加, 形成大陆下方的大陆根,造成大陆克拉通化和体积增生。大洋板块俯冲后在软流圈拆沉是岩石圈—软流圈物质循环的一种重要方式,对软流圈中物质均衡和体积稳定也起重要作用。     

塔里木板块与哥伦比亚超大陆的联系

塔里木拼贴时代和方式以及塔里木板块与哥伦比亚超大陆联系是塔里木板块形成演化中的关键问题,也是前寒武纪超大陆重建的重要问题,对塔里木盆地基底性质研究和油气勘探具有重要的理论意义和应用价值。本文首先通过南、北塔里木差异性对比分析和拼合时间的地质年代统计分析,探讨了形成统一的塔里木板块的时间问题。进一步基于大地构造比较学分析,将塔里木板块和扬子板块与世界其他板块的地质亲缘性开展综合对比分析,并结合古地磁数据分析和造山带及俯冲带对比分析,探讨了塔里木板块与哥伦比亚超大陆的关系。本文认为19～20亿年北塔里木向南塔里木俯冲并发生陆陆碰撞,形成了统一的塔里木板块。9～19亿年前塔里木板块、扬子板块与印度板块有较强的地质亲缘性,都处于哥伦比亚超大陆的西部边缘,并在地块周缘存在俯冲带,与北美板块东南缘的俯冲带具一定的可对比性;而华北板块与西伯利亚板块、波罗的板块亲缘性较强,位于古赤道附近,处于哥伦比亚超大陆的东部边缘。构造热事件的地质亲缘性表明塔里木、扬子和华北克拉通都是哥伦比亚超大陆周缘的小型克拉通,共同参与了哥伦比亚超大陆的汇聚过程。     

大洋俯冲和大陆碰撞沿走向的转换动力学及流体-熔体活动的作用

为了深入探讨大洋俯冲和大陆碰撞沿走向的转换及其动力学特征,同时更好的理解俯冲-碰撞带的流体-熔体活动及其效应,我们建立了一系列三维空间的大尺度、高分辨率的动力学数值模型。模拟结果显示,在板块会聚过程中,流体-熔体活动可以降低周围岩石的流变强度及两个板块之间的耦合作用,并能够促进大陆碰撞带俯冲板块的断离。同时,俯冲-碰撞带的空间转换模型揭示其深部结构存在巨大的沿走向的差异性,大陆碰撞带发生俯冲板块断离,而大洋俯冲板块持续下插。并且上覆板块的地壳物质发生从陆-陆碰撞带向洋-陆俯冲带的侧向逃逸。这种三维空间中沿走向的差异性俯冲-碰撞模式与中-东特提斯构造带相吻合,并揭示其动力学机制。     

青藏高原中段古近纪早期古构造演化

青藏高原古近纪早期发育大量区域逆冲推覆构造系统, 典型实例如冈底斯逆冲断裂系、纳木错西逆冲推覆构造、伦坡拉逆冲推覆构造、唐古拉山北逆冲推覆构造、东昆仑南部左旋斜冲断裂系。古近纪逆冲推覆构造对古新世—始新世沉积盆地具有重要控制和改造作用。冈底斯古新世—始新世早期发育大量中酸性岩浆侵入和多期中酸性火山喷发, 岩石Sr/Y-Y地球化学显示为岛弧岩浆岩, 推断与古近纪早期新特提斯残留古大洋板块俯冲存在成因联系。古近纪早期新特提斯残留大洋板块俯冲向印度大陆板块俯冲的转换时代约为46-45 Ma, 转换期前逆冲推覆构造运动与新特提斯残留古大洋板块俯冲存在密切关系; 转换期后印度大陆板块俯冲导致更为强烈的逆冲推覆构造运动和挤压缩短变形, 不仅使早期很多逆冲推覆构造继续发生构造运动, 还在喜马拉雅、冈底斯、风火山、东昆仑南部形成大量新的逆冲推覆构造系统。     

俯冲板块板内岩浆作用和动力学

地球上的岩浆活动主要发生于大洋中脊、俯冲带，而板内岩浆通常是由地幔柱或热点作用产生的。最近一二十年，在俯冲板块内部发现了一些岩浆活动，它们通常不能用传统的动力学机制来解释。本文综述了位于不同构造背景的俯冲板块内部的岩浆活动，包括大洋板块俯冲背景下俯冲的大洋和大陆板块部分，以及陆陆碰撞背景下俯冲的大陆板块。在此基础上，讨论了板片拉力在俯冲板块岩浆作用中的地位和效应，认为俯冲下盘微陆块的裂解通常需要多种因素的综合，并且需要多学科综合研究来鉴别地史上的俯冲板块以及相应的板内岩浆作用。俯冲板块中的板内岩浆的识别和研究将是板块构造理论框架下解释板内岩浆作用的重要补充。     

太平洋板块俯冲作用在东北亚大陆边缘的地质记录述评

古太平洋起源于泛大洋,为晚古生代-早中生代环绕泛大陆的全球性大洋。随着古特提斯洋盆的关闭和泛大陆的裂解,逐渐形成了古太平洋板块,以及大西洋、北冰洋和印度洋板块等等。本文综合了近年来这方面的研究进展,提出古太平洋板块(或伊佐柰琦板块)向东北亚大陆边缘的俯冲作用始于早侏罗世,俯冲带逐渐由西向东迁移,其中夹杂着微陆块或地体,构成了多岛洋的构造格局。     

东秦岭陡岭古岛弧和武当古弧后盆地及其地质意义

丹凤－信阳蛇绿混杂带作为秦岭－大别碰撞造山带主缝合带，其南部属于扬子板块北部大陆边缘。研究区域位于东秦岭南翼，是扬子板块北部大陆边缘的一部分。①晚元古－中震旦世，扬子板块北缘为活动型大陆边缘，发育陡岭岛弧和弧后盆地；②晚震旦－－早古生代，扬子板块北缘转为被动型大陆边缘，陡岭岛弧构成边缘地块，武发古弧后盆地演化为边缘盆地；③早古生代晚期，华北板块南缘的秦岭岛弧首先与扬子板块北缘的陡岭国缘地块（古岛弧     

西太平洋边缘构造特征及其演化

西太平洋边缘构造带是地球上规模最大最复杂的板块边界,以台湾和马鲁古海为界,自北往南大致可以分为3段。北段是典型的沟-弧-盆体系,千岛海盆、日本海盆及冲绳海槽均为典型的弧后扩张盆地。中段菲律宾岛弧构造带为双向俯冲带,构造复杂,新生代经历大的位移和重组,使得欧亚大陆边缘的南海、苏禄海和苏拉威西海成因存在很大的争议。南段新几内亚—所罗门构造带是太平洋板块、印度—澳大利亚及欧亚板块共同作用的结果,既有不同阶段的俯冲、碰撞,也有大规模的走滑与弧后的扩张,其间既有新扩张的海盆,又有正在俯冲消亡的海盆。台湾岛处于枢纽部位,欧亚板块在此被撕裂,南部欧亚大陆边缘南海洋壳沿马尼拉海沟俯冲于菲律宾岛弧之下,而北部菲律宾海洋壳沿琉球海沟俯冲欧亚大陆之下。马鲁古海是西太平洋板块边界又一转折点,马鲁古海板块往东下插于哈马黑拉之下,往西下插于桑义赫弧,形成反U形双向俯冲汇聚带,其洋壳板块已基本全部消失,致使哈马黑拉弧与桑义赫弧形成弧-弧碰撞。     

How was Taiwan created?

Since the beginning of formation of proto-Taiwan during late Miocene (9 Ma), the subducting Philippine (PH) Sea plate moved continuously through time in the N307° direction at a 5.6 cm/year velocity with respect to Eurasia (EU), tearing the Eurasian plate. Strain states within the EU crust are different on each side of the western PH Sea plate boundary (extensional in the Okinawa Trough and northeastern Taiwan versus contractional for the rest of Taiwan Island). The B feature corresponds to the boundary between the continental and oceanic parts of the subducting Eurasian plate and lies in the prolongation of the ocean–continent boundary of the northern South China Sea. Strain rates in the Philippines to northern Taiwan accretionary prism are similar on each side of B (contractional), though with different strain directions, perhaps in relation with the change of nature of the EU slab across B. Consequently, in the process of Taiwan mountain building, the deformation style was probably not changing continuously from the Manila to the Ryukyu subduction zones. The Luzon intra-oceanic arc only formed south of B, above the subducting Eurasian oceanic lithosphere. North of B, the Luzon arc collided with EU simultaneously with the eastward subduction of a portion of EU continental lithosphere beneath the Luzon arc. In its northern portion, the lower part of the Luzon arc was subducting beneath Eurasia while the upper part accreted against the Ryukyu forearc. Among the consequences of such a simple geodynamic model: (i) The notion of continuum from subduction to collision might be questioned. (ii) Traces of the Miocene volcanic arc were never found in the southwestern Ryukyu arc. We suggest that the portion of EU continental lithosphere, which has subducted beneath the Coastal Range, might include the Miocene Ryukyu arc volcanoes formed west of 126°E longitude and which are missing today. (iii) The 150-km-wide oceanic domain located south of B between the Luzon arc and the Manila trench, above the subducting oceanic EU plate (South China Sea) was progressively incorporated into the EU plate north of B.     

论构造耦合作用

构造耦合作用是一种普遍存在的地质现象。现今东、西太平洋的构造差异及古太平洋和现今太平洋大陆边缘构造差异与俯冲的洋壳板块性状有关,即:①俯冲角度;②俯冲角度的改变;③俯冲速率;④俯冲速率的改变;⑤俯冲深度;⑥俯冲板块前缘与海沟间的水平距离;⑦俯冲板块在670km上、下地幔界线处的构造形态;⑧俯冲板块的位移及位移方向。这种深部构造活动对浅部构造形成的制约和影响,是活动大陆边缘构造耦合现象的具体表现。中国西北部的盆山耦合现象是大陆内部的构造耦合作用,印度板块与欧亚板块碰撞产生的远距离效应,导致中亚地区产生陆内A型俯冲,A型俯冲是造成盆地消亡、山系形成的重要因素。     

西太平洋俯冲带的演变:来自东北亚陆缘增生杂岩的制约

本文系统总结了东北亚陆缘晚古生代和中生代增生杂岩的构成与形成时代,并结合同时代火成岩组合及其时空变异以及沉积建造组合,重塑了西太平洋板块俯冲带的演变历史.结果表明:①位于佳木斯地块东缘的跃进山杂岩代表了二叠纪俯冲带,它是古亚洲洋构造体制的产物;②侏罗纪增生杂岩代表了侏罗纪俯冲带,与陆缘同期钙碱性火成岩组合以及含煤建造一...     

川滇藏交界区二叠纪—早三叠世的两套弧火山岩

川滇藏交界区属三江印支造山带中段,地质构造十分复杂.文章据最近获得的岩石化学及野外调查资料分析了该区古特提斯活动大陆边缘的两套弧火山岩的特征,结果表明:早二叠世的吉东龙组是碧土洋盆向东俯冲的记录,当时的活动大陆边缘属西太平洋岛弧型;晚二叠-早三叠世的夏牙村组-马拉松多组是金沙江洋盆(南段)向西消减的证据,当时的活动大陆边缘接近安第斯型.在此基础上讨论它们在恢复古特提斯演化的时空制约中的意义.     

The role of slab melting in the petrogenesis of high-Mg andesites: evidence from Simbo Volcano,Solomon Islands

The petrogenesis of high-Mg andesites (HMA) in subduction zones involves shallow melting of refractory mantle sources or, alternatively, the interaction of ascending slab-derived melts with mantle peridotite. To unravel the petrogenesis of HMA, we report major, trace element and Sr–Nd–Hf–Pb isotope data for a newly found occurrence of HMA in the New Georgia group, Solomon Islands, SW-Pacific. Volcanism in the Solomon Islands was initiated by subduction of the Pacific plate beneath the Indian–Australian plate until a reversal of subduction polarity occurred ca. 10 Ma ago. Currently, the Indian–Australian plate is subducted northeastwards along the San Cristobál trench, forming the younger and still active southwestern Solomon island arc. However, a fossil slab of Pacific crust is still present beneath the arc. The edifice of the active volcano Simbo is located directly in the San Cristobál trench on top of the subducting Indian–Australian plate. Simbo Island lies on top of a strike-slip fault of the adjacent Woodlark spreading centre that is subducted beneath the Pacific plate. Geochemical and petrological compositions of volcanic rocks from Simbo are in marked contrast to those of volcanic rocks from islands north of the trench (mostly arc basalts). Simbo-type rocks are opx-bearing HMA, displaying 60–62 wt% SiO₂ but rather primitive Mg–Ni–Cr characteristics with 4–6 wt% MgO, up to 65 ppm Ni, up to 264 ppm Cr and Mg# from 67 to 75. The compositions of the Simbo andesites are explained by a binary mixture of silicic and basaltic melts. Relict olivine phenocrysts with Fo_88–90 and reaction-rims of opx also support a mixing model. The basaltic endmember is similar to back-arc basalts from the Woodlark Ridge. A slab melt affinity of the silicic mixing component is indicated by Gd_(N)/Yb_(N) of up to 2.2 that is higher if compared to MORB and other arc basalts from the Solomon Islands. ⁸⁷Sr/⁸⁶Sr, ɛNd and ɛHf values in the analysed rocks range from 0.7035 to 0.7040, +6.4 to +7.9 and +12 to +14.4, respectively. These values reveal the presence of the Indian–Australian mantle domain beneath Simbo (i.e. the Indian–Australian plate) and also beneath all other volcanic islands of the New Georgia group, which are located north of the San Cristobál trench. ²⁰⁶Pb/²⁰⁴Pb, ²⁰⁷Pb/²⁰⁴Pb and ²⁰⁸Pb/²⁰⁴Pb values (18.43–18.52, 15.49–15.55 and 18.13–18.34, respectively) confirm the presence of slab melts from the subducted Pacific plate beneath southern Simbo where the highest Gd_(N)/Yb_(N) ratios are reported. A spatial shift towards an Indian–Australian slab signature is observed when approaching the active San Cristobál trench on northern Simbo, reflecting the decreasing influence of slab melts from the old subducted Pacific plate.     

Tectonic collision processes after plate rupture

Rupture of a continental plate subducted below a forearc produces a fold and thrust mountain belt with fast overthrusting of nappes. Post-rupture plate unflexing leading to reflexure provides a mechanism for foreland basin formation. Application to the Australia-Banda Arc collision accounts for the origin of the Timor Trough, its imbrication and contemporaneous extension in outer arc, as well as reversal of subduction direction after the emplacement of nappes.     

华北陆块基底构造格局及早期大陆克拉通化过程

依据区域构造分析及同位素年代娄数据库,华北克拉通普质基底主要可以区划为以处构造单元：１）鄂尔多斯陆块新太古代被动边缘沉积;２）恒山－－承德太古代末期构造带;３）太古代末期五台－－登封岛弧带杂岩及构造缝合带;４）鲁西－－冀东－辽吉新太古代活动大陆边缘岩浆杂岩带;５）胶辽陆块;６）冀北－－固阳古元代初造山带及内蒙－＝东再造麻粒岩要带;７）吕梁－－中条古元古代裂谷带;８）辽南古元古代裂谷带。华北克拉通早     

http://www.sciencedirect.com/science/article/pii/S167498711400108X

We present three 3D numerical models of deep subduction where buoyant material from an oceanic plateau and a plume interact with the overriding plate to assess the influence on subduction dynamics,trench geometry,and mechanisms for plateau accretion and continental growth.Transient instabilities of the convergent margin are produced,resulting in:contorted trench geometry;trench migration parallel with the plate margin;folding of the subducting slab and orocline development at the convergent margin;and transfer of the plateau to the overriding plate.The presence of plume material beneath the oceanic plateau causes flat subduction above the plume,resulting in a "bowed" shaped subducting slab.In plateau-only models,plateau accretion at the edge of the overriding plate results in trench migration around the edge of the plateau before subduction is re-established directly behind the trailing edge of the plateau.The plateau shortens and some plateau material subducts.The presence of buoyant plume material beneath the oceanic plateau has a profound influence on the behaviour of the convergent margin.In the plateau + plume model,plateau accretion causes rapid trench advance.Plate convergence is accommodated by shearing at the base of the plateau and shortening in the overriding plate.The trench migrates around the edge of the plateau and subduction is re-established well behind the trailing edge of the plateau,effectively embedding the plateau into the overriding plate.A slab window forms beneath the accreted plateau and plume material is transferred from the subducting plate to the overriding plate through the window.In all of the models,the subduction zone maintains a relatively stable configuration away from the buoyancy anomalies within the downgoing plate.The models provide a dynamic context for plateau and plume accretion in Phanerozoic accretionary orogenic systems such as the East China Orogen and the Central Asian Orogen(Altiads),which are characterised by accreted ophiolite complexes with diverse geochemical affinities,and a protracted evolution of accretion of exotic terranes including oceanic plateau and terranes with plume origins.     

大南海地区新生代板块构造活动

在新生代澳大利亚板块和欧亚板块之间的大洋中，存在一些地块(微板块)；同时，澳大利亚板块北部边缘的一些地块先后和澳大利亚板块分离，向北运动，与一些和欧亚板块分离出来的地块先后发生碰撞缝合。在此期间，由于地块分离而发生海底扩张，产生许多小洋盆，如南海、苏录海、苏拉威西海、安达曼海等，最后形成了东南亚地区今日的构造景观。笔者从大南海地区新生代的构造演化史之框架来研究南海地区新生代的构造演化历史，认为南海地区新生代的构造活动既与印度板块和欧亚板块的碰撞有关，也与太平洋板块向欧亚板块的俯冲活动有联系；同时，还受到澳大利亚板块向北运动之影响。南海地区在新生代发生过两次海底扩张，第一次海底扩张发生在42～35Ma前．是受印度板块和欧亚板块碰撞而引起欧亚大陆之下向东南方向之地幔流的影响而发生的，其海底扩张方向为NWSE，产生了南海西南海盆；第二次海底扩张发生于32～17Ma前。由于太平洋板块向欧亚板块俯冲，俯冲的大洋岩石圈已达700km深处，阻挡了欧亚大陆的上地幔向东南方向之流动，从而转向南流动。引起南海地区南北向海底扩张，即新生代第二次海底扩张，产生了南海中央海盆。南海新生代洋盆诞生之后，由于大南海地区继续有地块碰撞和边缘海海底扩张，对南海南部地区产生挤压，从而使这里的沉积发生变形，这就引起万安运动(南海南部)。