台湾南部恒春海脊地质地球物理特征及其大地构造属性

恒春海脊的地质、地球物理特征与其相邻的南海海盆、吕宋火山弧和北吕宋海槽等地质构造单元所反映的特征明显不同 ,主要表现为低密度、弱磁性。推测其地壳性质为陆壳 ,是恒春半岛的南延部分。海脊西侧缓坡为陆缘增生楔 ,可见刺穿现象 ,这些刺穿构造是由逆冲挤压引起的泥底辟。海脊东部受弧陆碰撞的影响而急剧抬升。东部的弧陆碰撞是海脊抬升和增生楔形成的主要原因     

台湾南部恒春海脊地质地球物理特征及其大地构造属性

恒春海脊的地质,地球物理特征与其相邻的南海海盆,吕宋火山弧和北吕宋海槽等地质构造单元所反映的特征明显不同,主要表现为低密度,弱磁性,推测其地壳性质为陆壳,是恒春半岛的南延部分,海脊西侧缓坡为陆缘增生楔,可见刺穿现象,这些刺穿构造是由逆冲挤压引起的泥底辟,海脊东部受弧陆碰撞的影响而急剧抬升,东部的弧陆碰撞是海脊抬升和增生楔形成的主要原因。     

中国海区及邻域立体地貌图的设计与制作实践

中国海区及邻域立体地貌图既是一幅现代地图,又是一张绘画,构成了一幅"现代地图-地景画"。采取"一图三制"绘制方法,即陆地为地形晕渲法,大陆架使用形象示意法,深海区采用立体构图法。原图比例尺1:200万,垂直比例尺放大20倍。该图制作分两步:先绘制铅笔草图,再进行彩绘,完全手工绘制。该图展现了欧亚大陆板块东南部、大陆板块边缘及菲律宾海板块的地貌特征。区内地貌形成驱动力来自两条板块边界,即喜马拉雅碰撞带与西太平洋俯冲带。中国东部在E—W向老的构造基础上,叠加了新生代的NNE向构造,呈现网格状构造地貌格局。太平洋对大陆俯冲,拉开了日本海盆、冲绳海槽,形成2套沟弧盆体系。南海海盆是在陆缘引张下形成的,菲律宾弧北移并旋转,把南海围成边缘海。菲律宾弧北段与台湾岛碰撞,使中央山脉隆起,洋壳逆冲上陆,形成海岸山脉,台湾纵谷即板块缝合线。菲律宾海板块是太平洋板块一部分,在断裂基础上发生多次洋壳对洋壳俯冲,形成了洋缘沟弧盆地貌。     

南海东北部陆坡与恒春海脊天然气水合物分布的地震反射对比

经过对"探宝号"调查船在2001年8月在南海东北部陆坡及台湾南部恒春海脊海域采集的多道地震剖面资料进行的地震反射波数据分析、研究和解释,结果表明:(1)南海东北部陆坡段区域和台湾南部恒春海脊海域地震剖面上均显示有被作为天然气水合物存在标志的BSR,但两区域构造成因、形式和相关地质环境的不同造成了此两处的天然气水合物成因及过程的不同.(2)南海东北部陆坡区域的水合物形成与该区广泛发育的断裂带、滑塌构造体及其所形成的压力场屏蔽环境有关,而台湾南部恒春海脊海域的天然气水合物的形成则与马尼拉海沟俯冲带相关的逆冲推覆构造、增生楔等及其所对应的海底流体疏导体系有关.(3)南海陆缘区域广泛发育有各种断裂带、滑塌构造体、泥底辟、俯冲带、增生楔等,且温压环境合适,是天然气水合物矿藏极有可能广泛分布的区域.     

南海东北部陆坡与恒春海脊天然气水合物分布的地震反射特征对比

对“探宝号”调查船2001年8月在南海东北部陆坡及台湾南部恒春海脊海域采集的多道地震剖面资料进行了地震反射波数据分析、解释和研究,并对南海北部陆坡、陆隆及其东侧俯冲带等区域天然气水合物矿藏的成藏规律及分布特征作了初步的分析与探讨,结果表明:(1)南海东北部陆坡和台湾南部恒春海脊海域地震剖面上均显示有BSR,但两区域构造成因、形式和相关地质环境的不同造成了天然气水合物的成因及过程不同。(2)南海东北部陆坡区域的天然气水合物形成与该区广泛发育的断裂带、滑塌构造体及其所形成的压力场屏蔽环境有关,而台湾南部恒春海脊海域天然气水合物的形成则与马尼拉海沟俯冲带相关的逆冲推覆构造、增生楔及其所对应的海底流体疏导体系有关。(3)南海陆缘区域广泛发育有各种断裂带、滑塌构造体、泥底辟、俯冲带、增生楔等,且温压环境合适,是天然气水合物矿藏极有可能广泛分布的区域。     

台湾利吉混杂岩中蛇纹岩岩石学和U-Pb年代学及其地质意义

台湾利吉混杂岩位于吕宋岛弧与欧亚大陆发生碰撞(弧陆碰撞)关键地带,是菲律宾海板块和欧亚板块结合带重点研究的区域,其中出露的蛇纹岩可以为研究弧陆碰撞造山过程提供重要细节信息。利吉混杂岩中蛇纹岩岩块原岩为橄榄岩,通过锆石U-Pb年代学分析,得到代表洋壳年龄的橄榄岩形成年龄为17.7±0.5Ma,结合南海洋壳、菲律宾海洋壳年龄和构造背景,判断利吉混杂岩中的蛇纹岩(蛇纹石化橄榄岩)来自马尼拉俯冲系统的弧前盆地,是在利吉混杂岩形成过程中经第二次逆冲混入利吉混杂岩系统的。明确蛇纹岩岩块来源可以为利吉混杂岩形成提供细节信息,为研究弧陆碰撞造山活动和板块运动提供可靠依据。     

日本南海海槽俯冲带的地质特征及其构造意义

日本西南部的南海海槽是一个典型的俯冲系统，由菲律宾海板块向欧亚板块俯冲形成，其俯冲板片包含了九州-帕劳洋脊（KPR）、Kinan海山链、四国海盆和伊豆-小笠原岛弧（IBA）等多种地质单元。为了研究不同地质单元的板块俯冲效应，本文系统分析了南海海槽的地球物理和岩石地球化学特征。重力和热流特征显示南海海槽中部具有低的重力异常（-20–-40 mGal）和高的热流值（60–200 mW/m²），而东西两侧的热流值（20–80 mW/m²）较低。地震模拟结果显示俯冲板块的地壳厚度为5–20 km。地球化学结果表明俯冲板块的下覆地幔成分从西到东逐渐亏损。无震洋脊（如KPR、Kian海山链和Zenisu洋脊）的俯冲是控制南海海槽俯冲效应的主要因素。首先，无震洋脊的俯冲可能使上覆板块发生变形，沿着增生楔前缘出现不规则的地形凹陷。其次，无震洋脊的俯冲是大型逆冲地震的止裂体，阻碍了南海海槽1944年Mw 8.1和1946年Mw 8.3地震破裂的传播。此外，KPR和热的、年轻的四国海盆的俯冲会导致俯冲板片熔融，在日本岛弧上出现埃达克质岩浆活动，并为斑岩铜金矿床提供成矿物质。地球物理和地球化学特征的差异表明尽管IBA已经和日本岛弧发生碰撞，但作为IBA的残留弧，KPR仍然处于俯冲阶段，与日本岛弧之间有明显的地形分界，呈现单向收敛的状态。     

从地形与地质构造的关联对台湾附近3-D板块相互作用的新认识

近年台湾地质工作者与法国和荷兰人合作用最近的地形成果分别描绘了台湾南部及东北部沿马尼拉和琉球海沟的南中国海和菲律宾海俯冲板块。特别是根据地形剖面的近视图加上地震震源的分布讨论了台湾之下的 3 -D板块相互作用。其研究表明 :1东倾的南中国海板块可能向北追踪 ,一直到花莲的纬度 ;2大部分台湾岛之下的欧亚板块都俯冲到 670 km的深度不连续面 ;3在花莲所在经度稍西可勾绘出北倾的菲律宾海板块。因此 ,在台湾北部之下有板块的相互作用 ,在这里弧—陆碰撞是爆发性的 ;4可以设想在台湾海岸山脉之下俯冲的欧亚板块北部边沿曾发生板块…     

马尼拉俯冲带北段增生楔形态结构及演化过程

为揭示马尼拉增生楔的形态结构并加深对其演化过程的理解,本文对横穿马尼拉俯冲带北段的几条典型地震剖面进行了深度偏移处理,得到叠前深度偏移剖面和深度-速度模型,并对马尼拉增生楔的形态结构及内部特征进行了精细解释,将马尼拉增生楔分为原始沉积段、褶皱变形段、逆冲推覆段和背逆冲段四个部分,分别代表增生楔演化的不同阶段。推断马尼拉增生楔下部存在由早期仰冲的菲律宾海板块的残留块体构成的弧前基盘,弧前基盘是控制马尼拉增生楔形成演化的关键构造。弧前基盘前端是拆离滑脱面突然降阶并在地震剖面上"隐没"的部位;弧前基盘向增生楔底部的不断挤入导致了逆冲脱序断层的渐次发育以及增生楔向弧前基盘之上的不断爬升,导致了增生楔上、下陆坡地貌的分化,并为褶皱变形段和逆冲推覆段的地层形变提供了主要的应力。     

台湾西南近海地区构造特征

台湾岛位于沿菲律宾海西缘展布的琉球岛弧和吕宋岛弧的结合处．台湾岛以南，南海岩石圈向东俯冲到吕宋岛弧之下．台湾岛以东，菲律宾海板块向北俯冲到琉球岛弧之下．晚新生代，由于吕宋岛弧与亚洲大陆的碰撞，形成了台湾山带，台湾山带的构造走向为NNE－SSW，其弧凸向亚洲大陆．台湾岛内，西缘一系列的叠加精皱和推覆体很好地显示了造山构造特征，这些造山构造特征被认为向南延伸至台西南近海地区．然而，由于它们被较厚的第四纪沉积物所覆盖，台西南近海地区的构造模式多数尚属未知．据最近的一项海洋地球物理调查，马尼拉海沟沿NNW向…     

Geological Characteristics and Distribution of Submarine Physiographic Features in the Taiwan Region

The sea floor topography around Taiwan is characterized by the asymmetry of its shallow and flat shelves to the west and markedly deep troughs and basins to the south and east. Tectonics and sedimentation are major controls in forming the submarine physiographic features around Taiwan. Three Pliocene-Quaternary shelves are distributed north and west of Taiwan: East China Sea Shelf (passive margin shelf), the Taiwan Strait Shelf (foreland shelf), and Kaoping Shelf (island shelf) from north to south parallel to the strike of Taiwan orogen. Off northeastern Taiwan major morpho/tectonic features associated with plate subduction include E-W trending Ryukyu Trench, Yaeyama accretionary wedge, forearc basins, the Ryukyu Arcs, and the backarc basin of southern Okinawa Trough. Off eastern Taiwan lies the deep Huatung Basin on the Philippine Sea plate with a relatively flat floor, although several large submarine canyons are eroding and crossing the basin floor. Off southeastern Taiwan, the forearc region of the Luzon Arc has been deformed into five alternating N-S trending ridges and troughs during initial arc-continent collision. Among them, the submarine Hengchun Ridge is the seaward continuation of the Hengchun peninsula in southern Taiwan. Off southwestern Taiwan, the broad Kaoping Slope is the major submarine topographic feature with several noticeable submarine canyons. The Penghu Canyon separates this slope from the South China Sea Slope to the west and merges southwards into the Manila Trench in the northern South China Sea. Although most of sea floors of the Taiwan Strait are shallower than 60?m in water depth, there are three noticeable bathymetric lows and two highs in the Taiwan Strait. There exists a close relationship between hydrography and topography in the Taiwan Strait. The circulation of currents in the Taiwan Strait is strongly influenced by seasonal monsoon and semidiurnal tides. The Penghu Channel-Yunchang Ridge can be considered a modern tidal depositional system. The Taiwan Strait shelf has two phases of development. The early phase of the rift margin has developed during Paleoocene-Miocene and it has evolved to the foreland basin in Pliocene-Quaternary time. The present shelf morphology results mainly from combined effects of foreland subsidence and modern sedimentation overprinting that of the Late Pleistocene glaciation about 15,000 years ago.     

Geological Characteristics and Distribution of Submarine Physiographic Features in the Taiwan Region

The sea floor topography around Taiwan is characterized by the asymmetry of its shallow and flat shelves to the west and markedly deep troughs and basins to the south and east. Tectonics and sedimentation are major controls in forming the submarine physiographic features around Taiwan. Three Pliocene-Quaternary shelves are distributed north and west of Taiwan: East China Sea Shelf (passive margin shelf), the Taiwan Strait Shelf (foreland shelf), and Kaoping Shelf (island shelf) from north to south parallel to the strike of Taiwan orogen. Off northeastern Taiwan major morpho/tectonic features associated with plate subduction include E-W trending Ryukyu Trench, Yaeyama accretionary wedge, forearc basins, the Ryukyu Arcs, and the backarc basin of southern Okinawa Trough. Off eastern Taiwan lies the deep Huatung Basin on the Philippine Sea plate with a relatively flat floor, although several large submarine canyons are eroding and crossing the basin floor. Off southeastern Taiwan, the forearc region of the Luzon Arc has been deformed into five alternating N-S trending ridges and troughs during initial arc-continent collision. Among them, the submarine Hengchun Ridge is the seaward continuation of the Hengchun peninsula in southern Taiwan. Off southwestern Taiwan, the broad Kaoping Slope is the major submarine topographic feature with several noticeable submarine canyons. The Penghu Canyon separates this slope from the South China Sea Slope to the west and merges southwards into the Manila Trench in the northern South China Sea. Although most of sea floors of the Taiwan Strait are shallower than 60 m in water depth, there are three noticeable bathymetric lows and two highs in the Taiwan Strait. There exists a close relationship between hydrography and topography in the Taiwan Strait. The circulation of currents in the Taiwan Strait is strongly influenced by seasonal monsoon and semidiurnal tides. The Penghu Channel-Yunchang Ridge can be considered a modern tidal depositional system. The Taiwan Strait shelf has two phases of development. The early phase of the rift margin has developed during Paleoocene-Miocene and it has evolved to the foreland basin in Pliocene-Quaternary time. The present shelf morphology results mainly from combined effects of foreland subsidence and modern sedimentation overprinting that of the Late Pleistocene glaciation about 15,000 years ago.     

Segmentation of the Manila subduction system from migrated multichannel seismics and wedge taper analysis

Based on bathymetric data and multichannel seismic data, the Manila subduction system is divided into three segments, the North Luzon segment, the seamount chain segment and the West Luzon segment starts in Southwest Taiwan and runs as far as Mindoro. The volume variations of the accretionary prism, the forearc slope angle, taper angle variations support the segmentation of the Manila subduction system. The accretionary prism is composed of the outer wedge and the inner wedge separated by the slope break. The backstop structure and a 0.5–1 km thick subduction channel are interpreted in the seismic Line 973 located in the northeastern South China Sea. The clear décollement horizon reveals the oceanic sediment has been subducted beneath the accretionary prism. A number of splay faults occur in the active outer wedge. Taper angles vary from 8.0° ± 1° in the North Luzon segment, 9.9° ± 1° in the seamount segment to 11° ± 1° in the West Luzon segment. Based on variations between the taper angle and orthogonal convergence rates in the world continental margins and comparison between our results and the global compilation, different segments of the Manila subduction system fit well the global pattern. It suggests that subduction accretion dominates the north Luzon and seamount chain segment, but the steep slope indicates in the West Luzon segment and implies that tectonic erosion could dominate the West Luzon segment.     

南海北缘新生代盆地沉积与构造演化及地球动力学背景

南海北缘新生代沉积盆地是全面揭示南海北缘形成演化及与邻区大地构造单元相互作用的重要窗口。通过对盆地沉积-构造特征分析,南海北缘新生代裂陷过程显示出明显的多幕性和旋转性的特点。在从北向南逐渐迁移的趋势下,东、西段裂陷过程也具有一定的差异,西部裂陷活动及海侵时间明显早于东部,裂陷中心由西向东呈雁列式扩展。晚白垩世-早始新世裂陷活动应是东亚陆缘中生代构造-岩浆演化的延续,始新世中、晚期太平洋板块俯冲方向改变导致裂陷中心南移,印度欧亚板块碰撞效应是南海中央海盆扩张方向顺时针旋转的主要原因。     

Reestablishment of an accretionary prism after the subduction of a spreading ridge—constraints by a geometric model for the Golfo de Penas, Chile

Seismic studies offshore southern Chile have revealed the presence of a 70–80 km wide accretionary prism seaward of the Golfo de Penas (GPAP), where the Chile Ridge collided with the South American Plate between 3 and 6 Ma ago. Using the paleo-positions of the Chile Ridge relative to South America, the maximum age of this accretionary prism, which continues to be formed in the aftermath of the ridge–continent collision, has been estimated. Building on these earlier findings, this study presents a mass balance analysis based on a 2D model of accretionary wedge and trench geometry. This model can explain the relative importance of sedimentary fluxes and deformation front migration for the wedge restoration. The proposed model can also serve to evaluate the effects of fluctuations in (1) terrigenous sediment flux related to climate change, and (2) subduction channel thickness on the accretionary prism growth. Notably, the data reveal that the key parameters controlling the rebuilding of the GPAP are the terrigenous sediment flux (75 km²/10⁶ years), the relative advance of the deformation front (39.6 km/10⁶ years), and the thickness of the subduction channel (0.1 km). Moreover, the range of possible solutions for the observed size of the accretionary prism is narrowed by fitting the present-day thickness of sediments at the deformation front. Finally, climate-induced variations in sedimentary fluxes on the margin can affect the rate of growth of the accretionary prism during short periods of time (<100,000 years).     

Sediment compositions in offshore southern Taiwan and their relations to the source rocks in modern arc-continent collision zone

Modal analyses of 31 sand samples collected by piston coring document variations in sediment composition along and across the developing collision zone off southern Taiwan and help constrain sediment transport paths and, by inference, of sediment sources. Overall, sand composition from this region is dominated by lithic-fragment populations, with a QtFL average of Qt₂₇F₂₁L₅₂. Three geographic domains are based on morphotectonics and variations in sand composition: (1) South China Sea and the adjacent slope of the accretionary prism; (2) suture zone south of southern Taiwan and north of the Luzon forearc; and (3) the Luzon forearc basin (North Luzon Trough) and immediate adjacent slopes. Sands from the accretionary prism and the suture zone contain subequal amounts of sedimentary and metamorphic lithic fragments (Ls₅₁Lv₅Lm₄₅ and Ls₄₇Lv₅Lm₄₈), respectively, whereas sands from the forearc basin are dominated by volcanic lithic fragments (Ls₂₉Lv₄₉Lm₂₂). In addition, compositions of individual sand beds vary dramatically in the forearc basin. This heterogeneity indicates that sediments from different sources have been deposited sequentially, but do not typically mix during transport and deposition. Similar, but less dramatic, within-core variations occur over the accretionary prism.The major sediment input for the accretionary prism is from western Taiwan and is dominated by sedimentary and low-grade metamorphic lithic fragments. There appears to be a second sediment source, however, from southeastern China. This implies that a significant amount of sediment is the input from China to this region. The major component of sands in the suture zone is derived from Taiwan, but medium-grade metamorphic lithic fragments are rather sparse in these sands, considering the extensive and high-relief exposures of metamorphic rocks on the island of Taiwan. The major source of sands in the forearc basin is the active volcanoes of the Batan islands. Episodically, minor components appear to be fed to the forearc basin from the arcward slope of the accretionary prism, presumably by submarine mass wasting. This observation provides support for the hypothesized olistostromal origin for the Lichi Mélange of eastern Taiwan.     

Rapid subsidence of the Kikai Seamount inferred from drowned Pleistocene coral limestone: Implication for subduction of the Amami Plateau,northern Philippine Sea

Carbonate rock cores drilled on the Kikai Seamount, northern Philippine Sea are examined for better understanding of tectonic history of the northern Philippine Sea. The Kikai Seamount, the summit of which is at 1960 m water depth, is an isolated high on the northwestern part of the Amami Plateau formed by subduction-related arc volcanism, and is situated close to the axis of the Ryukyu Trench in front of the Ryukyu Arc, SW Japan. The seamount is capped with shallow-water carbonates such as coral rudstone. Detailed examinations of lithology, larger foraminiferal assemblages, and Sr isotope composition reveal that the core material comprises Miocene carbonates unconformably overlain by Early Pleistocene carbonates. It indicates rapid subsidence of the Kikai Seamount since the Early Pleistocene. The most probable cause of rapid subsidence is collision and subduction of the Amami Plateau laden with the Kikai Seamount. The rapid subsidence may have started when the western corner of the plateau reached the Ryukyu Trench and began subduction beneath the Ryukyu Arc. The onset of the subsidence is likely to be controlled by a motion change in the Philippine Sea Plate. The latest change in subduction direction from north to northwestward into northwestward to west has been believed to have occurred at 1-2 Ma during latest Pliocene to Early Pleistocene time. The change of direction resulted in the shift from oblique into right-angle subduction of the plate beneath the Ryukyu Arc and also the onset of the collision and subduction of the Amami Plateau.     

冲绳海槽构造活动的差异性及其非同步发展

冲绳海槽的地质和地球物理特征,特别是其构造活动性表明,海槽轴部存在一个扩张应力场,是弧后扩张形成的边缘盆地。其基本特征和构造活动性从东北至西南差别明显,具有南北分段的特点。据此作者把海槽分为扩张作用非同步发展的三段;东北段处在扩张前以裂陷为主的地堑或半地堑阶段;中段处于初始扩张过程的裂谷阶段;西南段则处于相对高级扩张的弧后盆地阶段。这种非同步发展可能是由于菲律宾海板块向亚洲大陆俯冲过程中,其速度在时间和空间上的差异性所致。     

Morphology and tectonics of the Yap Trench

We conducted swath bathymetry and gravity surveys the whole-length of the Yap Trench, lying on the southeastern boundary of the Philippine Sea Plate. These surveys provided a detailed morphology and substantial insight into the tectonics of this area subsequent the Caroline Ridge colliding with this trench. Horst and graben structures and other indications of normal faulting were observed in the sea-ward trench seafloor, suggesting bending of the subducting oceanic plate. Major two slope breaks were commonly observed in the arc-ward trench slope. The origin of these slope breaks is thought to be thrust faults and lithological boundaries. No flat lying layered sediments were found in the trench axis. These morphological characteristics suggest that the trench is tectonically active and that subduction is presently occurring. Negative peaks of Bouguer anomalies were observed over the arc-ward trench slope. This indicates that the crust is thickest beneath the arc-ward trench slope because the crustal layers on the convergent two plates overlap. Bouguer gravity anomalies over the northern portion of the Yap Arc are positive. These gravity signals show that the Yap Arc is uplifted by dynamic force, even though dense crustal layers underlie the arc. This overlying high density arc possibly forces the trench to have great water depths of nearly 9000 m. We propose a tectonic evolution of the trench. Subduction along the Yap Trench has continued with very slow rates of convergence, although the cessation of volcanism at the Yap Arc was contemporaneous with collision of the Caroline Ridge. The Yap Trench migrated westward with respect to the Philippine Sea Plate after collision, then consumption of the volcanic arc crust occurred, caused by tectonic erosion, and the distance between the arc and the trench consequently narrowed. Lower crustal sections of the Philippine Sea Plate were exposed on the arc-ward trench slope by overthrusting. Intense shearing caused deformation of the accumulated rocks, resulting in their metamorphism in the Yap Arc.     

The formation and tectonic evolution of Philippine Sea Plate and KPR

The Philippine Sea Plate has an extremely special tectonic background. As an oceanic plate, it is almost entirely surrounded by subduction zones with complex internal tectonic features. On the basis of enormous published literature, this paper offers a comprehensive overview of the tectonic and evolution history of the Philippine Basin and the Kyushu-Palau Ridge (KPR) in the Philippine Sea Plate, and discusses the geological features of KPR. Referring to relevant definitions of various "ridges" stipulated in United Nations Convention on the Law of the Sea, so the KPR is believed to be a remnant arc formed during the opening of the Parece Vela and Shikoku Basins in the Philippine Sea Plate. It is a submarine ridge on oceanic plate rather than a submarine elevation. And thus, it is not a natural component of the Japan continental margin.