中国台湾地区-菲律宾群岛深部纵横波结构成像及其构造意义

使用地震层析成像方法反演了中国台湾地区-菲律宾群岛的1197126条P波震相和1217821条S波震相,首次同时得到了该地区从地表到100km的纵横波速度结构。成像结果揭示了沿着马尼拉海沟向东俯冲的欧亚板块从中国台湾西南部到吕宋岛南端构造形态上的变化;中国台湾中央山脉由于受到造山运动的影响,地壳厚度可达55~60km,而山脉两侧的地壳厚度多为20~35km;此外,成像结果还提供了菲律宾海板块在中国台湾东北部及琉球海沟下方北向俯冲的地球物理学证据;研究区域南部的菲律宾群岛由于同时受到两侧欧亚板块和菲律宾海板块的双向俯冲,使得岛内的岩石圈变形严重,岛弧岩浆和地震活动十分发育;群岛东侧的菲律宾海板块在东吕宋海槽的活动性较弱,很可能是本哈姆海台的碰撞和俯冲所造成的,而菲律宾海板块在菲律宾海沟的俯冲活动则十分强烈,随着深度的增加逐渐向南发展。研究表明,板块俯冲造成了中国台湾地区-菲律宾群岛的地壳及上地幔具有较强的不均一性,这不仅孕育了大量的地震和火山活动,同时也对该地区的地质构造产生了深远的影响。     

欧亚东边缘的双向板块汇聚及其对大陆的影响

自3 Ma至现今,在欧亚东缘太平洋、菲律宾海板块以较大速率朝NWW方向运动,并沿海沟向欧亚大陆俯冲;同时欧亚板块以较小速率朝SEE方向移动,构成双方向的板块汇聚格局.沿日本岛弧东侧,海洋板片以较小的倾角插入欧亚大陆下面,在浅部产生的挤压变形扩展到日本海东边缘.琉球岛弧的中、北部,菲律宾海俯冲板片的倾角较大,其西南段由NE向转变为EW向,正经历活动的海沟后退与弧后扩张.台湾是3种板块汇聚的交点:欧亚沿马尼拉海沟向东俯冲,吕宋弧与台湾碰撞,使台湾岛陆壳东西向缩短与隆升,形成年轻的造山带,菲律宾海板块沿琉球海沟的西南段向北俯冲到欧亚下面.位于南海与菲律宾海之间的菲律宾群岛是宽的变形过渡带,两侧被欧亚向东、菲律宾海向西俯冲夹击,中间是大型左旋走滑断层.总体上,现今时期的太平洋、菲律宾海板块的西向俯冲运动所产生的变形主要分布在俯冲板片内部及岛弧,未扩散到弧后地区,可能这种俯冲运动产生的水平应力较小,不能阻挡欧亚大陆的向东移动,对大陆内部的现今构造没有明显的影响.     

台湾南部～菲律宾地区的地震分布、应力状态及板块的相互作用

利用ＩＳＣ地震资料研究了台湾南部～菲律宾群岛的地震空间分布和ｍ＿ｂ≥５．０的机制解，讨论了俯冲带的形态和地壳及俯冲带上的应力状态，并结合地质和地球物理的研究结果，认为南海次板块的东部边界是由台湾西南俯冲带、马尼拉俯冲带、内格罗斯俯冲带、哥达巴都俯冲带组成，菲律宾海板块的西部边界由东吕宋海槽俯冲带、菲律宾海俯冲带组成。菲律宾群岛是一个形变过渡带，由于该过渡带的存在，南海次板块俯冲于菲律宾群岛之下，菲律宾海板块对南部的影响很弱     

南海东部现时地壳运动、震源机制及晚中新世以来的板块相互作用

南海东部的板块汇聚带是了解南海和菲律宾海晚中新世以来构造演化的一个重要窗口.针对这一区域地壳运动的研究,获得了该区内微块体的现时地壳运动特征及其动力机制,在此基础上结合俯冲板片形态和震源机制资料提出了该区晚中新世以来的板块汇聚作用特征.研究发现:晚中新世晚期,菲律宾海板块西缘在南、北部的西向运动均受到限制的情况下,位于中间区域的吕宋岛北部则由于其西侧相对自由而继续往NW方向运动.该过程中,菲律宾大断裂等汇聚带内部的走滑断裂对于协调不同块体之间的地壳运动速度差异有着重要作用.受南、北阻挡的影响,中间部分的西向运动速率呈现出中间大(吕宋岛北部)两端小的特征.因而北吕宋西侧的马尼拉海沟也以相对于南部更快的速率不断向NW迁移.然而俯冲的南海岩石圈受其下方SE向地幔流的影响,未能发生相应的俯冲板片后撤,而是在两板块之间的直接接触面形成强烈推挤并发生反向弯曲.结合这一板块作用特征认为,马尼拉海沟现今的构造形迹是在上述背景下北段多次向NW方向变迁形成的,而双火山弧的形成则主要是由菲律宾海板块在吕宋岛弧南、北部的西向运动速率差异引起的.     

菲律宾海板块与欧亚板块的相互作用及其对东亚构造运动的影响

根据菲律宾海的演化,指出菲律宾海板块的特点:以俯冲边界为主,易于产生形变.将理论结果与地球物理、地质以及GPS测量结果进行比较,发现菲律宾海板块内部及边界有明显形变.讨论了菲律宾海板块与欧亚板块的相互作用,指出其相互作用有明显的分段性.在南海海槽一带有较强的挤压,在琉球海沟一带由于两板块耦合较弱及冲绳海槽的开裂,没有形成对东亚大陆的挤压;台湾附近两板块碰撞,对中国东南形成较强的挤压;在菲律宾群岛一带形成两板块间的复杂变形带,使两板块间的作用减弱.     

马尼拉俯冲带的地震层析成像研究

基于国际地震中心的P波走时数据和层析成像反演方法,获得了具有较高分辨率的马尼拉俯冲带的深部速度模型.结果表明,（1）高速的南海俯冲板片沿马尼拉俯冲带的俯冲形态随纬度发生变化,在14°N和16°N之间,板片俯冲角度较大,俯冲深度可达400~500 km,在17°N附近,俯冲板片角度和深度较南部变小,而在18°N附近,俯冲板片以近垂直角度俯冲到地幔转换带;（2）17°N和18°N之间俯冲角度的变化意味着南海板片发生了撕裂;（3）在14°N附近,南海板片由300 km以上的近垂直俯冲转为200~300 km深度的近水平展布,与震源分布存在较大的差异,表明南海板片发生了撕裂,并且导致410 km间断面抬升.根据成像结果计算的不同位置南海板片的俯冲长度和时间表明,南海板片俯冲之前的面积为现今面积的两倍,14°N最先开始发生俯冲,并由南向北扩展.     

中国大陆地壳应力场与构造运动区域特征研究

系统研究了1918～2006年间中国大陆及其周缘发生的3115个M4.6以上中、强地震的震源机制解,得到中国大陆地壳区域应力场的压应力轴和张应力轴空间分布的统计结果.探讨了大陆应力场的结构,以及周围板块运动对中国大陆应力场影响作用范围及其界线.结果表明,中国东部的华北地区受到太平洋板块向欧亚板块俯冲挤压的同时,又受到从贝加尔湖经过大华北直至琉球海沟的广阔范围内存在的方位为170°引张应力场的控制.华北地区大地震的震源机制解反映出,该区地震发生为NEE向挤压应力和NNW向张应力的共同作用结果.印度洋板块向欧亚板块的碰撞挤压运动所产生的强烈的挤压应力,控制了喜马拉雅、青藏高原、乃至延伸到天山及其以北的广大地区.在青藏高原周缘地区和中国西部的大范围内,压应力P轴水平分量位于20°~40°,形成了近北东方向的挤压应力场,大量逆断层型强震集中发生在青藏高原的南、北和西部周缘地区以及天山等地区. 本文结果表明,正断层型地震集中发生在青藏高原中部高海拔的地区.证明了青藏高原周缘区域发生南北向强烈挤压短缩的同时,中部高海拔地区存在着明显的近东西向的扩张运动.根据本文最新结果,得到了华北、华南块体之间地壳区域应力场的控制边界线,发现该分界线与大地构造、岩石圈板块构造图等有较大差异,特别是在大别及其以东地区, 该分界线向东南偏转,在沿海的温州附近转向东,最终穿过东海直至琉球海沟.台湾纵谷断层是菲律宾海板块与欧亚板块之间碰撞挤压边界,来自北西西向运动的菲律宾海板块构造应力控制了从台湾纵谷、华南块体,直到中国南北地震带南段东部地域的应力场. 地震震源机制结果还表明,南北地震带南段西侧其P轴大约为NNE方向,与青藏高原的P轴方位一致.南北地震带南段东侧其P轴大约为NWW方向,与华南块体的P轴方位一致.因此,将中〖JP2〗国大陆分成东、西两部分的南北地震带南段是印度洋板块与菲律宾海板块在中国大陆内部影响控制范围的分界线.     

中国周边板块的相互作用及其对中国应力场的影响——(Ⅱ)印度板块的影响

本文利用地震资料并结合地质资料,讨论了印度板块与欧亚板块在中国周边的相互作用及其对中国应力场的影响,指出两板块在喜马拉雅山前断裂地区碰撞,碰撞边界向西延续到35°N,74°E附近,其主要挤压方向为NNE,并形成SE方向的物质流动.帕米尔地区有强烈的构造运动,并存在俯冲带形态的构造.在26.5°N,97°E附近,板块边界的走向发生突变,并形成东倾的缅甸山弧俯冲带,但印度板块挤压造成的主压应力方向为NNE向.在安达曼—尼科巴—苏门答腊—爪哇岛弧,印度板块俯冲于欧亚板块之下,在中国南海一带形成NNW向或近Ns向的主压应力.     

1999年台湾7.6级大震后江苏-南黄海地区中强震分析预测

1　江苏—南黄海地区中强震与台湾 7级强震的相关关系江苏—南黄海地区 ( 3 1°～ 3 5.5°N,1 1 8°～ 1 2 4 .5°E)地处扬州—铜陵地震带中东段 ,位于华北地震区与华南地震区的交接部位 ,这里是我国东部地震活动水平较高的地区 ,众所周知 ,太平洋板块、菲律宾板块对欧亚板块的俯冲挤压 ,是我国大陆东部地区地震活动的主要动力源。 1 999年 9月 2 1日台湾 7.6级大震的发生 ,使得本区在 1 994～ 1 997年 4年中强震连发的形势之下又面临一场严峻的考验。表 1　台湾地区 7级强震与江苏—南黄海地区中强震之间相关关系序号台湾地区江苏—南黄海…     

台湾岛南部海域的前碰撞构造地球物理特征

在2001年进行了一次从南海跨越吕宋岛弧到西菲律宾海的海洋地球物理调查, 获得了一条高质量深反射地震剖面. 以此地震剖面的解释为基础, 结合重磁数据的正反演, 系统分析了台湾岛南部海域的区域构造地球物理学特征, 特别是相邻块体之间碰撞拼接前的构造关系以及不同块体的构造属性, 以帮助更好地认识形成台湾岛造山带的早期弧陆碰撞过程. 马尼拉增生楔的组成及自西向东的递进变形表明南海的俯冲经历过多个次级俯冲活跃阶段. 北吕宋海槽内存在活跃的前碰撞地壳缩短过程, 导致地层倾角产生6°~13°的倾斜, 但是由地层倾斜而造成的缩短量只占区域总缩短量的很小的一部分. 吕宋岛弧的东翼比岛弧的其他部分显得更为活跃, 在东翼的弧内盆地内存在活动断裂与褶皱作用. 磁反演结果表明吕宋岛弧可能经历了多期次的岩浆过程, 造成磁性横向不均一性. 布格重力异常及重力正反演结果显示花东海盆具有明显高于南海和吕宋岛弧的地壳和上地幔密度, 且与南海北部之间存在较大的海底深度差异, 表明花东海盆与南海北部不可能如前人认为的在整体或部分上曾经属于同一个洋壳. 加瓜海脊作为一片隆升的洋壳, 可能由早期菲律宾海板块在加瓜海脊东侧短暂的西北向俯冲有关. 所有证据表明台湾岛南部海域正在进行多块体的拼接, 为一大陆增长的典型地区.     

马尼拉俯冲带缺失中深源地震成因初探

马尼拉俯冲带是整个南海地震活动多发区,地震成因与南海的形成和构造演化关系密切.对马尼拉俯冲带地震数据和层析成像结果进行了深入分析.结果表明:马尼拉俯冲带的地震活动主要为密集的浅源地震,缺失中深源地震.进一步分析揭示:①脱水和榴辉岩的形成在南海洋壳到达软流圈前就基本停止.马尼拉俯冲带南部在较浅的深度就转变为塑性变形,并停...     

DEEP VELOCITY STRUCTURE AND ITS TECTONIC IMPLICATIONS IN SOUTHERN PHILIPPINES

3-D V_P and V_S images of southern Philippines at the 0~100km depths are generated by inverting a large number of travel-time data from the International Seismological Centre(1960-2017)through seismic tomography method. The results show lateral variation exists in the crust and upper mantle:High V_P and V_S anomalies emerge in mid-west Mindanao and Bohol Island, which might be caused by the combined action of huge magmatism and ophiolite accretion in the lower crust; low velocity anomalies of the upper mantle in the west of Mindanao are consistent with locations of volcanoes on the surface. It, thus, could be inferred that the low velocity anomaly is closely related to magmatic activity. The dense earthquake distribution along plate margin extending to 100km coincides with the strong activity of the Philippine Sea Plate which is located in the northeast and southeast of Mindanao. Relative weak activity of Sulawesi Sea Basin is presented simultaneously. The subduction of the Philippine Sea Plate is mostly concentrated in the crust and the top of the uppermost mantle. Our tomographic images show that lateral heterogeneities exist in the crust and uppermost mantle of the southern Philippines. Low V_P and V_S anomalies emerge in Philippine Trench and Cotabato Trench, in contrast, high V_P and V_S anomalies appear in shallow crust of land area where a large number of earthquakes and magmatic activities develop. This may reflect strong tectonic processes between the Philippine Sea Plate and Philippine Mobile Belt. Low V_P and V_S anomalies in the crust of eastern Mindanao coinciding with the location of volcanoes on the surface may show partial melting of crust material caused by dehydration of the subducting Philippine Sea Plate. Such a similar phenomenon can be also seen in the south of Negros Island and Cotabato Trench. Thus we infer that active tectonic behaviors are constrained within the crust of the Philippine Sea Plate, Sulu Sea Basin and Sulawesi Basin.Low V_P and V_S anomalies of the mantle in the mid-west of Mindanao island are associated with magmatic activity which may be caused by a collision between the east and west part of Mindanao at 5Ma. The fracture system in the west of Mindanao provides the possible passage ways of mantle hot material upwelling, coinciding with the model of geothermal distribution in this area. According to the geochemical analysis, ophiolite observed in Sanbaoyan and the western part of Mindanao could indicate material composition from crust to upper mantle on Eurasian continental margin which may show the evidence of rapid expansion environment of mid-ocean ridge. High V_P and V_S anomalies in the mantle of northeast and southeast of Mindanao coinciding with the distribution of massive earthquake along boundaries show a well agreement with the shape of the Philippine Sea Plate. Dense earthquake distribution in south Mindanao at 100km shows the Philippine Sea Plate has strong activity and stress accumulation in the upper mantle. On the contrary, the seismicity in southwest Mindanao and Cotabato Trench reduces rapidly at the depth from 50km to 100km, revealing weak subduciton and stress release of Sulawesi Basin in the mantle.     

Silicic arc volcanism in Central Luzon, the Philippines: Characterization of its space, time and geochemical relationship

Abstract   The silicic volcanic rocks in Central Luzon show a temporal and spatial relationship with its geochemistry. Volcanic centers dated to approximately 5 Ma are silicic in geochemical composition whereas those between <5–1 Ma expose basaltic to andesitic rocks. Volcanic centers dated <1 Ma are characterized by a wide range of geochemistry encompassing basaltic through andesitic to dacitic signatures. Aside from changes in geochemistry through time, the areas (i.e. fore-arc to back-arc region) where the volcanic centers are formed also vary. The shift in the location of the volcanic centers in Central Luzon is attributed to changes in the dip of subduction of the South China Sea crust along the Manila Trench. Flat subduction resulted from the subduction of the Scarborough Seamount Chain, an oceanic bathymetric high along the Manila Trench west of northern Luzon. However, collision of Luzon with Taiwan in the north and Palawan in the south resulted in steepening of the subduction angle. The silicic volcanic centers in the forearc (Ce/Yb = 20–140) and back-arc (Ce/Yb = 20–60) regions are generally characterized by higher Ce/Yb compared to the basaltic-andesitic volcanic rocks in the main volcanic arc (Ce/Yb = 20) and back-arc (Ce/Yb = 20–30) regions. This across-arc geochemical variation highlights the contributions from the slab, mantle and crust coupled with the effects of geochemical processes that include partial melting, fractionation, magma mixing and mantle–melt interaction.     

Collision, subduction and accretion events in the Philippines: A synthesis

Abstract The Philippines preserves evidence of the superimposition of tectonic processes in ancient and present‐day collision and subduction zone complexes. The Baguio District in northern Luzon, the Palawan–Central Philippine region and the Mati–Pujada area in southeastern Mindanao resulted from events related to subduction polarity reversal leading to trench initiation, continent‐arc collision and autochthonous oceanic lithosphere emplacement, respectively. Geological data on the Baguio District in Northern Luzon reveal an Early Miocene trench initiation for the east‐dipping Manila Trench. This followed the Late Oligocene cessation of subduction along the west‐dipping proto‐East Luzon Trough. The Manila Trench initiation, which is modeled as a consequence of the counter‐clockwise rotation of Luzon, is attributed to the collision of the Palawan microcontinental block with the Philippine Mobile Belt. In the course of rotation, Luzon onramped the South China Sea crust, effectively converting the shear zone that bounded them into a subduction zone. Several collision‐related accretionary complexes (e.g. Romblon, Mindoro) are present in the Palawan–Central Philippine region. The easternmost collision zone boundary is located east of the Romblon group of islands. The Early Miocene southwestward shift of the collision boundary from Romblon to Mindoro started to end by the Pliocene. Continuous interaction between the Palawan microcontinental block and the Philippine Mobile Belt is presently taken up again along the collisional boundary east of the Romblon group of islands. The Mati–Pujada Peninsula area, on the other hand, is underlain by the Upper Cretaceous Pujada Ophiolite. This supra‐subduction zone ophiolite is capped by chert and pelagic limestones which suggests its derivation from a relatively deep marginal basin. The Pujada Ophiolite could be a part of a proto‐Molucca Sea plate. The re‐interpretation of the geology and tectonic settings of the three areas reaffirm the complex geodynamic evolution of the Philippine archipelago and addresses some of its perceived geological enigmas.     

汕头－吕宋岛岩石圈速度结构与震源构造──台湾浅滩7．3级地震构造之一

汕头－吕宋岛岩石圈速度结构剖面，划分出华南陆缘古生代陆壳、陆架区晚古生代－中生代陆壳、陆坡带中生代－早第三纪过渡壳、新生代南海海盆洋壳及吕宋岛中生代－新生代岛弧陆壳与东吕宋海槽洋壳等地壳构造组分，并确定了上述地壳构造之间的边界断裂构造及其性质。结合地震震源分布及机制，初步确定了华南陆架盆岭构造带北、南两侧地震构造的控震构造与发震构造性质及其震源力学特征；１）指出１９９４年９月１６日台湾浅滩７．３级地震属于板缘壳幔地震及造成一千公里有感范围的原因；２）马尼拉海沟的海底地堑构造与南海海盆岩石圈地幔上隆是马尼拉海沟俯冲带震源显示正断层性质的原因，且为被动的或转换俯冲带；３）东吕宋海槽仍属于菲律宾海俯冲带性质；吕宋岛东西两侧俯冲带岩石圈板片震源深度的准三层分布，可能表明俯冲带岩石圈板片存在相应的低速滑移层。     

Focal mechanism solutions and its tectonic significance in the trench of the eastern South China Sea

Introduction South China Sea (SCS) is located in the convergence zone between Euro-Asian plate, Pacific plate (Philippine plate) and Indian plate. Interactions of three plates made the crust of this region suffer tectonic stress in many directions and made the South China Sea be in the complex environ-ment of the tectonic stress. There are four different marginal types in the surrounding of the South China Sea: The tectonic zone of the rifting margin in the north of SCS, the NS direct…     

利用非线性方法反演琉球-台湾-吕宋地区的岩石层P波速度结构

根据中国地震台网和ISC台站提供的P波走时资料,使用差异演化全局优化算法(DE算法)和移动窗方法反演了琉球-台湾-吕宋地区岩石层尺度的P波速度结构.在台站和地震分布较为密集的地区,反演窗口为2°×2°,移动步长为1°;在台站和地震较少的地区,反演窗口为4°×4°左右,移动步长为2°.反演结果揭示出琉球-台湾-吕宋地区壳幔结构的横向差异:琉球岛弧西侧受冲绳海槽地幔热扰动的地壳减薄,东侧由于菲律宾海板决的俯冲挤压地壳略有增厚;欧亚大陆与菲律宾海板块的相互碰撞导致台湾地区地壳及岩石层明显增厚;吕宋及菲律宾北部岩石层受岛弧火山下方热流影响较大.结果表明,非线性全局优化算法和移动窗方法能够用于反演较大尺度速度结构的横向变化.     

宽频带海底地震仪的地震重定位对马尼拉俯冲板片形态的约束

将宽频带OBS用于海底天然地震长期观测,在国内尚处于实验阶段.2015年在马尼拉俯冲带北段开展了为期6个月的宽频带海底天然地震观测试验.根据回收的1台海底地震仪(OBS04)与国际地震台网的718台陆地地震台站,共记录到7562个P波走时和5002个S波走时数据,利用Hyposat地震定位方法,对马尼拉俯冲带北部(119°E—123°E,19°N—22°N)在2015年8月至2016年2月期间的264个地震进行了重定位.地震重定位的结果及定位误差分析表明,在海域布设的OBS04台站让地震观测的空间分布更为合理,提高了地震定位精度;重定位后的震中分布更为集中,与地质构造吻合良好;浅部的地震活动较为活跃,分布密集,与浅部断层发育有关;重定位后的4条震源深度投影剖面,从不同角度较好地约束了俯冲板片上边界的板片形态,板片倾角在浅部0～30km区间约为10°～22°,随着深度的增加,俯冲板片逐渐变陡,在深度120～180km处倾角约为41°～58°.该项研究为马尼拉俯冲带北段的板片形态提供了重要约束,而且为今后长期天然地震观测提供了重要而宝贵的经验与借鉴.     

Some features of the arc-continent collision zone in the Ryukyu subduction system, Taiwan Junction area

Abstract To the northeast of Taiwan, northwestward subduction of the Philippine Sea plate is occurring beneath the Eurasian plate along the Ryukyu Trench. The Ryukyu Trench, which is well defined along the northeastern part of the Ryukyu arc, cannot be easily defined west of 123° east. This is an area where the Gagua Ridge (whose origin is controversial) enters the trench from the south. On the basis of the marine geophysical survey data the following results have been obtained. The structural elements associated with the Ryukyu subduction system deform and partially disappear west of 123° east. Among other things the Ryukyu Trench terminates close to the western slope of the Gagua Ridge. The Gagua Ridge is the result of tectonic heaping and is likely to be an uplifted sliver of oceanic crust. The interaction between the Ryukyu subduction system and the Taiwan collision zone encompasses a wide region from Taiwan to the longitude 124.5° east. The Gagua Ridge is a boundary between the active deformation zone related to the collision in Taiwan and the West Philippine Basin. It is proposed that there is a tectonic zone that can be traced from the Okinawa Trough on the north to the southern termination of the Gagua Ridge on the south.