Seismicity of the Hellenic subduction zone in the area of western and central Crete observed by temporary local seismic networks

Temporary local seismic networks were installed in western Crete, in central Crete, and on the island Gavdos south of western Crete, respectively, in order to image shallow seismically active zones of the Hellenic subduction zone.More than 4000 events in the magnitude range between −0.5 and 4.8 were detected and localized. The resulting three-dimensional hypocenter distribution allows the localization of seismically active zones in the area of western and central Crete from the Mediterranean Ridge to the Cretan Sea. Furthermore, a three-dimensional structural model of the studied region was compiled based on results of wide-angle seismics, surface wave analysis and receiver function studies. The comparison of the hypocenter distribution and the structure has allowed intraplate and interplate seismicity to be distinguished.High interplate seismicity along the interface between the subducting African lithosphere and the Aegean lithosphere was found south of western Crete where the interface is located at about 20 to 40 km depth. An offset between the southern border of the Aegean lithosphere and the southern border of active interplate seismicity is observed. In the area of Crete, the offset varies laterally along the Hellenic arc between about 50 and 70 km.A southwards dipping zone of high seismicity within the Aegean lithosphere is found south of central Crete in the region of the Ptolemy trench. It reaches from the interface between the plates at about 30 km depth towards the surface. In comparison, the Aegean lithosphere south of western Crete is seismically much less active including the region of the Ionian trench. Intraplate seismicity within the Aegean plate beneath Crete and north of Crete is confined to the upper about 20 km. Between 20 and 40 km depth beneath Crete, the Aegean lithosphere appears to be seismically inactive. In western Crete, the southern and western borders of this aseismic zone correlate strongly with the coastline of Crete.     

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。     

Synthesis of Palaeozoic deformational events and terrane accretion in the Canadian Appalachians

Plate tectonic theory predicts that most deformation is associated with subduction and terrane accretion, with some deformation associated with transform/transcurrent movements. Deformation associated with subduction varies between two end members: (1) where the tectonic regime is dominated by subduction of oceanic lithosphere containing small terranes, a narrow surface zone of accretionary deformation along the subduction zone starts diachronously on the subducting plate at the trench as material is transferred from the subducting plate to the over-riding plate; and (2) where continent-continent collision is occurring, a wide surface zone of accretionary deformation starts synchronously or with limited diachronism. Palaeozoic deformational events in the Canadian Appalachians correspond to narrow diachronous events in the Ordovician and Silurian, whereas Devonian, Carboniferous and Permian deformational events are widespread and broadly synchronous. Along the western side of the Canadian Appalachians, the Taconian deformational event starts diachronously throughout the Ordovician and corresponds to the north-north-west accretion of the Notre Dame, Ascot-Weedon, St Victor and various ophiolitic massifs (volcanic arc and peri-arc terranes) over cratonic North America. Within the eastern half of the Central Mobile Belt, the Late Cambrian-Early Ordovician Penobscotian deformational event corresponds to the ?south-easterly accretion of the Exploits subzone (various volcanic are and peri-arc terranes) over the Gander Zone (?continental rise). In the centre of the orogen, the Late Ordovician-Silurian Beothukan deformational event corresponds to the south-easterly accretion of the Notre Dame over the Exploits-Gander subzones. Along the south-eastern side of the Central Mobile Belt, the Silurian Ganderian deformational event corresponds to the north-north-east, sinistral transcurrent accretion of the Avalon Composite Terrane (microcontinent) over the Gander-Exploits zones. Along the south-eastern half of the orogen, the Late Silurian-Middle Devonian Acadian deformation event corresponds to the westerly accretion of the Meguma terrane (intradeep or continental rise) over the Avalon Composite Terrane. Affecting the entire orogen, the Late Devonian, Carboniferous and Permian, Acadian-Alleghanian deformational events correspond to the east-west convergence between Laurentia and Gondwana (continent-continent collision).     

Single subduction zone for the generation of Devonian ophiolites and high‐P metamorphic belts of the Variscan Orogen (NW Iberia)

Within the Variscan Orogen, Early Devonian and Late Devonian high‐P belts separated by mid‐Devonian ophiolites can be interpreted as having formed in a single subduction zone. Early Devonian convergence nucleated a Laurussia‐dipping subduction zone from an inherited lithospheric neck (peri‐Gondwanan Cambrian back‐arc). Slab‐retreat induced upper plate extension, mantle incursion and lower plate thermal softening, favouring slab‐detachment within the lower plate and diapiric exhumation of deep‐seated rocks through the overlying mantle up to relaminate the upper plate. Upper plate extension produced mid‐Devonian suprasubduction ocean floor spreading (Devonian ophiolites), while further convergence resulted in plate coupling and intraoceanic ophiolite imbrication. Accretion of the remaining Cambrian ocean heralded Late Devonian subduction of inner sections of Gondwana across the same subduction zone and the underthrusting of mainland Gondwana (culmination of NW Iberian allochthonous pile). Oblique convergence favoured lateral plate sliding, and explained the different lateral positions along Gondwana of terranes separated by Palaeozoic ophiolites.     

Creation of the Cocos and Nazca plates by fission of the Farallon plate

Throughout the Early Tertiary the area of the Farallon oceanic plate was episodically diminished by detachment of large and small northern regions, which became independently moving plates and microplates. The nature and history of Farallon plate fragmentation has been inferred mainly from structural patterns on the western, Pacific-plate flank of the East Pacific Rise, because the fragmented eastern flank has been subducted. The final episode of plate fragmentation occurred at the beginning of the Miocene, when the Cocos plate was split off, leaving the much reduced Farallon plate to be renamed the Nazca plate, and initiating Cocos–Nazca spreading. Some Oligocene Farallon plate with rifted margins that are a direct record of this plate-splitting event has survived in the eastern tropical Pacific, most extensively off northern Peru and Ecuador. Small remnants of the conjugate northern rifted margin are exposed off Costa Rica, and perhaps south of Panama. Marine geophysical profiles (bathymetric, magnetic and seismic reflection) and multibeam sonar swaths across these rifted oceanic margins, combined with surveys of 30–20 Ma crust on the western rise-flank, indicate that (i) Localized lithospheric rupture to create a new plate boundary was preceded by plate stretching and fracturing in a belt several hundred km wide. Fissural volcanism along some of these fractures built volcanic ridges (e.g., Alvarado and Sarmiento Ridges) that are 1–2 km high and parallel to “absolute” Farallon plate motion; they closely resemble fissural ridges described from the young western flank of the present Pacific–Nazca rise. (ii) For 1–2 m.y. prior to final rupture of the Farallon plate, perhaps coinciding with the period of lithospheric stretching, the entire plate changed direction to a more easterly (“Nazca-like”) course; after the split the northern (Cocos) part reverted to a northeasterly absolute motion. (iii) The plate-splitting fracture that became the site of initial Cocos–Nazca spreading was a linear feature that, at least through the 680 km of ruptured Oligocene lithosphere known to have avoided subduction, did not follow any pre-existing feature on the Farallon plate, e.g., a “fracture zone” trail of a transform fault. (iv) The margins of surviving parts of the plate-splitting fracture have narrow shoulders raised by uplift of unloaded footwalls, and partially buried by fissural volcanism. (v) Cocos–Nazca spreading began at 23 Ma; reports of older Cocos–Nazca crust in the eastern Panama Basin were based on misidentified magnetic anomalies.There is increased evidence that the driving force for the 23 Ma fission of the Farallon plate was the divergence of slab-pull stresses at the Middle America and South America subduction zones. The timing and location of the split may have been influenced by (i) the increasingly divergent northeast slab pull at the Middle America subduction zone, which lengthened and reoriented because of motion between the North America and Caribbean plates; (ii) the slightly earlier detachment of a northern part of the plate that had been entering the California subduction zone, contributing a less divergent plate-driving stress; and (iii) weakening of older parts of the plate by the Galapagos hotspot, which had come to underlie the equatorial region, midway between the risecrest and the two subduction zones, by the Late Oligocene.     

华北地块南部巨型陆内俯冲带与秦岭造山带岩石圈现今三维结构

豫西横穿秦岭造山带的反射地震为主的综合地球物理探测，发现秦岭现今北界存在华北地块南部自北向南向秦岭的巨型陆内俯冲带，深达Ｍｏｈｏ面以下，与之相伴而生，在中上地壳发育自南向北的逆冲推构造带，千公里东西向延伸，主要发生于晚白垩世１００Ｍａ±，成为秦岭与华北地区块间中新生代重要陆内构造，它是秦岭造山带岩石圈现今三维结构的基本要素和组成部分，秦岭造山带岩石圈现今结构具有流变学分层的“立交桥”三维结构框架模型。显然它们具有统一的动力学背景，是秦岭造山带现今处于印度－青藏、太平洋和欧亚板块的西伯利亚地块等三大构造动力学体系复合部位，导致其从深部地幔动力学的最新调整到上部地壳响应所发生的壳幔等圈层相互作用的综合产物，可能是大陆长期保存、演化的主要途径与形式之一，具有重要的大陆动力学意义，对中国大陆构造、灾害、环境研究也具重要意义。     

Ordovician Macquarie Arc and turbidite fan relationships,Lachlan Orogen,southeastern Australia: stratigraphic and tectonic problems

Ordovician rocks of the Lachlan Orogen consist of two major associations, mafic to intermediate volcanic and volcaniclastic rocks (Macquarie Arc), which aerially comprise several north–south-trending belts, and the quartz-rich turbidite succession. Relationships between these associations are integral to resolving their tectonic settings and opinions range between contacts being major thrusts, combinations of various types of faults, and stratigraphic contacts with structural complications. Stratigraphic contacts between these associations are found with volcaniclastic-dominant units overlying quartz-turbidite units along the eastern boundary of the eastern volcanic belt and along the southern boundary of the central volcanic belt. Mixing between these major associations is limited and reflects waning quartzose turbidite deposition along a gently sloping sea floor not penetrating steeper volcaniclastic aprons that were developing around the growing volcanic centres formed during late Middle Ordovician to early Silurian Macquarie Arc igneous activity. An island arc setting has been most widely supported for the Macquarie Arc, but the identification and polarity of the associated subduction zone remain a contentious issue particularly for the Early Ordovician phase of igneous activity. The Macquarie Arc initiated within a Cambrian backarc formed by sea-floor spreading behind a boninitic island arc and presumably reflects a renewed response to regional convergence as subduction ceased along the Ross–Delamerian convergent boundary at the East Gondwana continental margin. An extensional episode accompanied initiation of the late Middle Ordovician expansion in island arc development. A SSE-dipping subduction zone is considered to have formed the Macquarie Arc and underwent anticlockwise rotation about an Euler pole at the western termination of the island arc. This resulted in widespread deformation west of the Macquarie Arc in the Benambran Orogeny and development of subduction along the eastern margin of the orogenic belt.     

The North Fork porphyry copper deposit of the Washington Cascades

The North Fork porphyry copper deposit in the Cascade volcanic arc of Washington displays copper mineralization confined to the potassic (biotite) and phyllic (sericite) alteration zones. No secondary potassium feldspars have been found in either alteration zone; moreover, chemical analyses indicate the potassic alteration zone contains a low K₂O content. Argillic and propylitic zones are also recognized, but these are barren of hypogene copper mineralization. Biotite-chalcopyrite intergrowths in the deposit have been given a 9.9 K-Ar age. Thus it is not only one of the youngest deposits dated in the western Cordillera, but it is associated with a volcanic arc which has no current Benioff zone seismic array or accompanying trench. The deposit appears to have developed during the period when coupling of the North American and Juan de Fuca plates probably inhibited subduction under the Cascade volcanic arc.     

柴达木北缘超高压变质带形成与折返的时限及机制

位于青藏高原北缘的祁连山加里东造山带的形成是阿拉善板块、祁连微板块及柴达木一东昆仑板块在加里东期间汇聚和碰撞的结果。祁连微板块和柴达木一东昆仑板块之间的柴(达木)北缘超高压变质带形成于495～440Ma,是继南祁连洋壳向北俯冲于祁连微板块下形成增生的柴北缘火山岛弧带之后,陆壳深俯冲的产物。柴北缘超高压变质带是在祁连微板块及柴达木一东昆仑板块之间的“正向陆内俯冲”向“斜向陆内俯冲”转化过程中“斜向挤出”机制下折返的,开始折返年龄为470～460Ma,最后的折返时间为400～406Ma。折返构造很好地保存在超高压变质岩石中,并且记录了广泛的退变质作用。     

New petrological data on the volcanic rocks of the Chichinautzin region: The sources of the magmatic melts and the origin of the Trans-Mexican volcanic belt

New petrographic, isotopic-geochemical, and mineralogical data are presented for the volcanic rocks of the Chichinautzin region of the Trans-Mexican volcanic belt (TMVB). The geological setting and the peculiarities of the composition of the volcanic rocks from different regions of the belt are compared to the plume-related volcanic rocks from the areas of the Gulf of California, Central America, and the Galapagos hot spot. It was concluded that the composition of the intraplate rocks from the western and eastern parts of the TMVB was subjected to the Californian and Galapagos plumes, respectively. In its turn, the ascending mantle plumes provoke melting of the subcontinental lithospheric mantle related to the formation of islandarc rocks. The model of the consecutive propagating rifting in the eastward direction suggested by some researchers (Marquez et al., 1999; Verma, 2001) instead of the subduction hypothesis is in agreement with the geological and geophysical data and the isotopic-geochemical peculiarities of the volcanic rocks within the TMVB.     

洋板块地质研究进展

中国存在多个时代、多种类型的造山带,发育了多种多样的俯冲增生杂岩带,经历了复杂多变的洋陆转换过程,如何揭示包括洋内演化和洋陆转换等的造山过程一直是一个难题。为此,中国区域地质志项目组提出了洋板块地质研究,试图通过对造山系俯冲增生杂岩带、蛇绿岩带等洋岩石圈地质建造、结构构造进行系统研究,再造洋岩石圈从洋中脊形成到海沟俯冲消亡、转换成陆的地质作用全过程。本文介绍了洋板块地质提出到现今主要的研究进展,包括四个方面。一是,初步建立了洋板块地质格架,洋板块地质的研究包括俯冲增生杂岩的物质组成、蛇绿岩类型及其形成的构造环境、洋板块沉积组合和洋板块地层、岛弧火成岩组合、洋陆转换的过程和机制、洋-陆转换过程与成矿作用等重要内容。二是,识别出北山牛圈子—马鬃山、嘉荫—依兰、陈蔡、东昆仑布青山—阿尼玛卿、鹰扬关、大洪山、甘孜—理塘、新余神山—新干神政桥等中国陆域62条主要的俯冲增生杂岩带/增生杂岩带。俯冲增生杂岩带是认识、理解造山系时空结构、组成和演化的关键。三是,在祁连地区识别出较为完整的洋内弧岩石组合。洋盆演化形成大陆过程中的洋内俯冲带是大陆的诞生地,洋内俯冲作用形成的洋内弧是洋盆演化形成大陆的初始弧。洋内弧火成岩组合序列的发现为研究洋陆转换过程提供了岩石学依据。祁连造山带是洋板块地质研究的经典地区之一。研究显示,当金山出露完整的洋内弧岩石组合,这些岩石记录了洋内弧从初始俯冲到发育成熟的全过程,为探讨祁连造山带原特提斯洋构造演化提供了新的依据。四是,制定了洋板块地质构造图编图方案,编图内容主要包括俯冲增生杂岩带、岩浆弧、高压-超高压带、俯冲期和碰撞期构造形变要素和构造演化等。编图单元分为三级:一级为俯冲增生杂岩带;二级为岩片;三级包括基质和岩块。编图过程中需要明确岩浆弧的性质和归属,明确图面上某一岩浆弧与哪个蛇绿混杂岩或大洋配套。图面上对于构造要素的表达重点是区分俯冲和碰撞阶段。通过构造变形的时态、相态、位态研究,识别俯冲期和碰撞期的构造变形形迹。这是洋板块地质初步的研究成果,以俯冲增生杂岩带的研究为基础,探讨特提斯洋等大洋的演化、中国东部古太平洋/太平洋转换与中新生代成矿关系等重大基础地质问题是洋板块地质研究下一步的工作方向。目前,洋板块地质的研究还处于试点阶段,洋板块地质与成矿的成因联系等重大地质问题尚需今后更深入地研究。     

Mesozoic interaction of the Kula plate and the western margin of north america

Oceanic crust west of North America at the beginning of the Jurassic belonged to the Kula plate. The development of the western margin of North America since the Jurassic reflects interaction with the Kula plate, the Kula-Farallon spreading center and the Farallon plate. The Kula plate ceased to exist in the Paleocene and later developments were caused by interaction of the Farallon plate and, subsequently, collision with the East Pacific Rise.At the beginning of the Jurassic, when spreading between North and South America began, the Kula-Farallon-Pacific triple junction moved to the north relative to North America, and the eastern end of the Kula-Farallon spreading center swept northwards along the continental margin.During the Paleocene, Kula-Pacific spreading ceased and the Kula plate fused to the Pacific plate. Throughout the Mesozoic, subduction of the Kula plate took place along the Alaskan continental margin. When the Kula plate joined the Pacific plate a new subduction zone formed along the line of the present Aleutian chain.Wrangellia and Stikinia, anomalous terrains in Alaska and northwestern Canada respectively, were emplaced by transport on the Kula plate from lower latitudes. Hypotheses which require transport of these plates in the Mesozoic from the “far reaches of the Pacific” ignore the problem of transport across either the Kula-Pacific or Kula-Farallon spreading centers. The interaction of the Kula plate and western North America throughout the Jurassic and the Cretaceous should result in emplacement of these terrains by motion oblique to the continental margin. Tethyan faunas in Stikinia must come from the western end of Tethys between North and South America, not the Indonesian region at the eastern end of Tethys.As the northeastern end of the Kula-Farallon ridge moved northward, the sense of motion changed from right lateral shear between the Kula and North American plates to collision or left lateral shear between the Farallon and North American plates. Left lateral shear along zones analogous to the Mojave-Sonora megashear may have been the means by which anomalous terrains were transported to the southeast into the gap between North and South America forming present day Central America. Such a model overcomes the overlap difficulties suffered in previous attempts to reconstruct the Mesozoic paleogeography of Central America.     

中国东南部晚中生代俯冲带探索

根据岩浆弧位置变化追溯俯冲板块的俯冲角度变化的原理计算了１８０－８５Ｍａ时段内,古太平洋板块向欧亚大陆俯冲的俯冲角变化（从大约１０°增大至约８０°）,讨论了导致俯冲板块俯冲角变化的原因和由此引起的岩浆活动的时空变化,以及它对中国东南部地质构造的影响。     

江绍断裂带晚侏罗世S型酸性火山岩特征及其地质意义

岩石化学、地球化学特征研究结果表明,江绍断裂带赣东北段广丰—上饶地区的晚侏罗世酸性火山岩是中地壳变质沉积源岩改造成因的Ｓ型火山岩．通过横向对比发现,该区火山岩与前人已认识的、江绍断裂带西延部分的相山、东乡Ｓ型酸性火山岩盆地构成了一条沿江绍断裂带展布的Ｓ型酸性火山岩带,这一特殊成因的火山岩及其空间分布规律,很可能是晚侏罗世华夏与扬子两板块陆内碰撞俯冲的结果．     

Neocene and Quaternary extent and geometry of the subducted Pacific Plate beneath North Island, New Zealand: Implications for Kaikoura tectonics

The extent and geometry of the obliquely subduced oceanic Pacific Plate beneath North Island, New Zealand, for five million year intervals through the mid-Miocene to Quaternary, are presented in a series of maps and cross-sections. These show that the subducted plate progressively increased its extent from NE to SW beneath the North Island, and in the more northern regions where it was first emplaced, concomitantly increased its dip from 10° to 50°.The changing extent and geometry of the subducted slab has been established from the age pattern of orogenic andesites and from the geochemical K₂O-h parameter of depth of magma generation. The radiometric dates show a migration of the volcanic front back towards the trench at an average rate of 20 km/My. The trenchward migration is explained by a model of increasing slab dip which is corroborated by the K₂O data calibrated against the presently active arc (Taupo Volcanic Zone). With the exception of northern Coromandel Peninsula, the andesitic magmas were generated at 85–100 km depth. The interpretation of the dates adopted here indicates that the subducted slab originated at the NE-SW trending Kermadec-Hikurangi Trench, and implies a different and much simpler evolution of the Australia-Pacific plate boundary in the vicinity of North Island than other recent models.Subduction geometry has been found elsewhere to be a principal influence upon the state of stress and deformational style in an over-riding plate. The possibility is explored that the timing, nature and pattern of the Neogene to Quaternary Kaikoura Orogeny in North Island is due to this influence. Apart from the effect of oblique subduction in eastern North Island, there is an accord between the onset of deformation and the emplacement sequence of the shallow slab beneath North Island, and between the change in subduction geometry and a progressive north to south change in northern North Island from compression to extension.     

大洋岛弧的前世今生

正这些年来似乎地球变小了,人的寿命变长了,90寻常,80刚迈入老年人之列。一些同事和学生为庆祝叶大年院士八十华诞及从事科研六十载在岩石学报出版一期论文专辑,邀请我作序,这才惊奇叶大年院士已近杖朝之年,我和他交往甚密,经常见面就觉不出有什么变化,也就觉不出他的年龄增长。叶大年老师和我是亦师亦友的关系。我称他老师是名正言顺的。最早见到他是在河南许昌地区的野外     

Collision of the Kronotskiy arc at the NE Eurasia margin and structural evolution of the Kamchatka–Aleutian junction

Structural evolution of the Kamchatka–Aleutian junction area in late Mesozoic and Tertiary was generally controlled by (1) the processes of subduction in Kronotskiy and Proto-Kamchatka subduction zones and (2) collision of the Kronotskiy arc against NE Eurasia margin. Two structural zones of the pre-Pliocene age and six structural assemblages are recognized in studied region. 1: Eastern ranges zone comprises SE-vergent thrust folded belt, which evolved in accretionary and collisional setting. Two structural assemblages (ER1 and ER2), developed there, document shortening in the NW–SE direction and in the N–S direction, respectively. 2: Eastern Peninsulas zone generally corresponds to Kronotskiy arc terrane. Four structural assemblages are recognized in this zone. They characterize (1) precollisional deformations in the accretionary wedge (EP1) and in the fore-arc basin and volcanic belt (EP2), and (2) syn-collisional deformation of the entire Kronotskiy terrane in plunging folds (EP3) and deformations in the foreland basin (EP4). Analysis of paleomagnetic declinations versus present day structural strike in the Kronotskiy arc terrane shows that originally the arc was trending from west to east. Relative position of the accretionary wedge, fore-arc basin and volcanic belt, as well as northward dipping thrusts in accretionary wedge indicate, that a northward dipping subduction zone was located south of the arc. The accretionary wedge developed from the Late Cretaceous through the Eocene, and it implies that the subduction zone maintained its direction and position during this time. It implies that Kronotskiy arc was neither a part of the Pacific nor Kula plates and was located on an individual smaller plate, which included the arc and Vetlovka back-arc basin. Motion of the Kronotskiy arc towards Eurasia was connected only with NW-directed subduction at Kamchatka margin since Middle Eocene (42–44 Ma). Emplacement of the Kronotskiy arc at the Kamchatka margin occurred between Late Eocene and Early Miocene. This is based on the age of syn-collisional plunging folds in Kronotskiy terrane, and provenance data for the Upper Eocene to Middle Miocene Tyushevka basin, which indicate in situ evolution of the basin with respect to Kamchatka. Collision was controlled by the common motion of the Kronotskiy arc with Pacific plate towards the northwest, and by the motion of the Eurasian margin towards the south. The latter motion was responsible for the southward deflection of the western part of the Kronotskiy arc (EP3 structures), and for oblique transpressional structures in the collisional belt (ER2 structures).     

Subsidence and strike-slip tectonism of the upper continental slope off Manzanillo, Mexico

The direction of convergence between the Rivera and North American plates becomes progressively more oblique (in a counter-clockwise sense as measured relative to the trench-normal direction) northwestward along the Jalisco subduction zone. By analogy to other subduction zones, the forces resulting from this distribution of convergence directions are expected to produce a NW moving, fore-arc sliver and a NW–SE stretching of the fore-arc area. Also, a series of roughly arc parallel strike-slip faults may form in the fore-arc area, both onshore and offshore, as is observed in the Aleutian arc.In the Jalisco subduction zone, the Jalisco block has been proposed to represent such a fore-arc sliver. However, this proposal has encountered one major problem. Namely, right-lateral strike-slip faulting within the fore-arc sliver, and between the fore-arc sliver and the North American plate, should be observed. However, evidence for the expected right-lateral strike-slip faulting is sparse. Some evidence for right-lateral strike-slip faulting along the Jalisco block–North American plate boundary (the Tepic–Zacoalco rift system) has been reported, although some disagreement exists. Right-lateral strike-slip faulting has also been reported within the interior of the Jalisco block and in the southern Colima rift, which forms the SE boundary of the Jalisco block.Threefold, multi-channel seismic reflection data were collected in the offshore area of the Jalisco subduction zone off Manzanillo in April 2002 during the FAMEX campaign of the N/O L'Atalante. These data provide additional evidence for recent strike-slip motion within the fore-arc region of the Jalisco subduction zone. This faulting offsets right-laterally a prominent horst block within the southern Colima rift, from which we conclude that the sense of motion along the faulting is dextral. These data also provide additional evidence for recent subsidence within the area offshore of Manzanillo, as has been proposed.     

Tectonics of the Aegean block: Rotation, side arc collision and crustal extension

A new tectonic model for the Aegean block is outlined in an effort to explain the widespread extension observed in this region. A key element in this model is the concept of “side arc collision” This term is used to describe the interaction of subducted oceanic lithosphere with continental lithosphere in a subduction arc in which oblique subduction occurs. In the Hellenic arc side arc collision is proposed for the northeast corner near Rhodes. The collision involves subducted African lithosphere, moving to the northeast almost parallel to the arc, with the continental mass of southwest Turkey. It affects the motion of the Anatolian-Aegean plate complex, but is not similar to continental collision since it occurs mostly at depth and involves only little, if any, of the shallow and rigid part of the continental lithosphere. The model assumes that Anatolia and the Aegean are part of one plate complex which undergoes counterclockwise rotation; if it were not for the side arc collision near Rhodes, the two blocks would exhibit similar deformation and might, in effect, be indistinguishable. At present, however, free and undisturbed rotation is possible only for the Anatolian block (excluding western Anatolia) where the motion is accommodated by subduction along the Cyprean arc. Further west the side arc collision inhibits this rotation along the subduction front. Still further west, undisturbed subduction along the central and western parts of the Hellenic arc is again possible and is well documented. On the other side of the Anatolian-Aegean plate complex, relatively free motion occurs along the North Anatolian fault zone including in the Aegean Sea. The combination of this motion in the north with the local obstruction of the rotation near Rhodes, must create a torque and a new pattern of rotation for the western part of the plate complex, thus creating a separate Aegean block. Since, however, the two blocks are not separated by a plate boundary, the Aegean block cannot move freely according to the new torque. Effective motion of the Aegean block relative to Europe and Anatolia, particularly in the north, is achieved through extension of the crust (lithosphere?). Thus the greatest amount of deformation (extension) is observed along the suture zone between the two blocks and, in particular, in the northeastern part of the Aegean block where motion relative to Anatolia must be greatest.     

云南维西地区中三叠世双峰式火山岩成因及其对金沙江弧盆形成演化的制约

金沙江缝合带及其西侧发育的岩浆活动记录了大洋俯冲-碰撞过程,是反演大洋演化的关键。江达-维西陆缘弧维西地区的中三叠世火山岩（崔依比组）在时空上构成独特的双峰式火山岩组合,以基性火山岩与大量酸性火山岩交互出现为主要特征,流纹岩LA-ICP-MS锆石U-Pb年龄为244±1.3 Ma,表明崔依比组火山岩形成于中三叠世晚期。地球化学分析结果显示,玄武岩亏损Nb、Ta、Ti等高场强元素,Zr含量、Zr/Y值和（Th/Nb）N值低,兼具板内及弧火山岩的双重特性;流纹岩相对富硅,贫TiO2和MgO,具有较低的Al2O3,富集Rb、Ba等大离子亲石元素,亏损Nb等高场强元素,Sr、Ti均具有弱的负异常特征,也兼具有板内及弧火山岩的双重特性。综合认为,维西地区中三叠世崔依比组双峰式火山岩形成于与板块俯冲过程有关的板内伸展环境,是金沙江洋壳西向俯冲过程中板片断离导致区域伸展背景下岩浆活动的产物。