西秦岭关家沟组物源分析

西南秦岭摩天岭地区关家沟组的时代、沉积环境及构造背景一直是争论的焦点。对关家沟组粉砂岩、板岩进行了常量、微量及稀土元素地球化学分析表明关家沟组物源主要来自活动大陆边缘的岛弧环境。以本区地层斜层理产状及砾石优选方位为依据,对关家沟组岩层古水流方向综合分析,推测其古水流方向为230°~356°,以北西向为主;砾石的优选方位在228°~338°之间,以北北西向为主;砾石分布特征由南向北颗粒由大逐渐变小、磨圆度由差至较好、优选方位由杂乱到较好的变化趋势。结合前人成果,关家沟组应属于碧口弧前盆地系统内,推测关家沟组内的沉积物主要来自南东向的岛弧。     

Petrological and geochemical characteristics of the Samar Ophiolite ultramafic section: implications on the origins of the ophiolites in Samar and Leyte islands,Philippines

Cretaceous ophiolites and ophiolitic fragments occur in the Samar and Leyte islands in eastern central Philippines. The Samar Ophiolite is a complete crust–mantle sequence exposed in southern Samar, whereas the Tacloban and Malitbog ophiolite complexes are, respectively, located in the northeastern and southwestern portions of the nearby Leyte island. Despite the close proximity of these islands, the genetic relationship of these ophiolites and ophiolitic complexes, if any, remains to be elucidated. We present here new petrographic and geochemical data on the harzburgites and dunites of the ultramafic section of the Samar Ophiolite. These mantle peridotites are highly depleted residues which have low modal pyroxene content, high spinel Cr# (=0.62–0.79), and slightly enriched light rare earth element abundance with depletion in Zr and Ti. Such characteristics are typical of supra-subduction zone peridotites and strongly contrast with the abyssal signatures of the Tacloban and Malitbog ophiolite complexes. The absence of a structure between these adjacent ophiolite fragments initially hints that they form a single oceanic crust. However, with our new results, we suggest other possible mechanisms that could explain the relationship of these ophiolites.     

Geology and geochronology of the Emu Creek Block (northern New South Wales,Australia) and implications for oroclinal bending in the New England Orogen

The southern part of the New England Orogen exhibits a series of remarkable orogenic bends (oroclines), which include the prominent Z-shaped Texas and Coffs Harbour oroclines. The oroclines are defined by the curvature of Devonian–Carboniferous forearc basin and accretionary complex rock units. However, for much of the interpreted length of the Texas Orocline, the forearc basin is mostly concealed by younger strata, and crops out only in the Emu Creek Block in the eastern limb of the orocline. The geology of the Emu Creek Block has hitherto been relatively poorly constrained and is addressed here by presenting new data, including a revised geological map, stratigraphic sections and new detrital zircon U–Pb ages. Rocks of the Emu Creek Block include shallow-marine and deltaic sedimentary successions, corresponding to the Emu Creek and Paddys Flat formations, respectively. New detrital zircon U–Pb data indicate that these formations were deposited during the late Carboniferous and that strata were derived from a magmatic source of Devonian to Carboniferous age. The sedimentary provenance and detrital zircon age distribution suggest that the sequence was deposited in a forearc basin setting. We propose that the Emu Creek and Paddys Flat formations are arc-distal, along-strike correlatives of the northern Tamworth Belt, which is part of the forearc basin in the western limb of the Texas Orocline. These results confirm the suggestion that Devonian–Carboniferous forearc basin rocks surround the Texas Orocline and have been subjected to oroclinal bending.     

Did boninite originate from the heterogeneous mantle with recycled ancient slab?

Boninites are widely distributed along the western margin of the Pacific Plate extruded during the incipient stage of the subduction zone development in the early Paleogene period. This paper discusses the genetic relationships of boninite and antecedent protoarc basalt magmas and demonstrates their recycled ancient slab origin based on the T–P conditions and Pb–Hf–Nd–Os isotopic modeling. Primitive melt inclusions in chrome spinel from Ogasawara and Guam islands show severely depleted high‐SiO₂, MgO (high‐silica) and less depleted low‐SiO₂, MgO (low‐silica and ultralow‐silica) boninitic compositions. The genetic conditions of 1 346 °C at 0.58 GPa and 1 292 °C at 0.69 GPa for the low‐ and ultralow‐silica boninite magmas lie on adiabatic melting paths of depleted mid‐ocean ridge basalt mantle with a potential temperature of 1 430 °C in Ogasawara and of 1 370 °C in Guam, respectively. This is consistent with the model that the low‐ and ultralow‐silica boninites were produced by remelting of the residue of the protoarc basalt during the forearc spreading immediately following the subduction initiation. In contrast, the genetic conditions of 1 428 °C and 0.96 GPa for the high‐silica boninite magma is reconciled with the ascent of more depleted harzburgitic source which pre‐existed below the Izu–Ogasawara–Mariana forearc region before the subduction started. Mixing calculations based on the Pb–Nd–Hf isotopic data for the Mariana protoarc basalt and boninites support the above remelting model for the (ultra)low‐silica boninite and the discrete harzburgite source for the high‐silica boninite. Yb–Os isotopic modeling of the high‐Si boninite source indicates 18–30 wt% melting of the primitive upper mantle at 1.5–1.7 Ga, whereas the source mantle of the protoarc basalt, the residue of which became the source of the (ultra)low‐Si boninite, experienced only 3.5–4.0 wt% melt depletion at 3.6–3.1 Ga, much earlier than the average depleted mid‐ocean ridge basalt mantle with similar degrees of melt depletion at 2.6–2.2 Ga.     

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。     

Cambrian (~510 Ma) ophiolites of the East Kunlun orogen,China: A case study from the Acite ophiolitic tectonic mélange

The Acite ophiolitic mélange represents a remnant of the Proto-Tethys forearc oceanic lithosphere. Two gabbros yield zircon ²⁰⁶Pb/²³⁸U ages of 510-512 Ma. The magmatic rocks are divided into three subtypes: (1) Mid-ocean ridge basalt (MORB) -like forearc basalts (FABs), (2) Low-titanium tholeiitic gabbros (LTGs), and (3) Normal calc-alkaline dacites (CADs). The FABs have comparatively higher TiO₂ concentrations (1.13–1.42 wt%) and show almost flat REE patterns. In the NMORB normalized trace element patterns, the FABs display flat distributions of high field strength element (HFSE). The ε_Nd(t) values of FABs range from +4.0 to +4.8. These features are similar to the composition of Izu-Bonin-Mariana forearc basalts (FABs). LTGs are characterized by higher contents of MgO (8.85–9.95 wt%) and lower concentration of TiO₂(0.29–0.50 wt%). They show LREE-depleted patterns, however having comparatively lower total REE contents than those of FABs. The ε_Nd(t) values of LTGs range from +7.4 to +8.4. These features show that LTG magmas originated from a progressively depleted mantle source. In contrast, the CADs having higher SiO₂ contents (63.58–70.92 wt%) have higher total REE contents. In the NMORB normalized trace element patterns, CADs are characterized by enrichment of LILEs and depletion of HFSEs. CADs have negative ε_Nd(t) values ranging from -9.8 to -10.5, which are likely suggestive of a crust-derived source. The rock association of FABs and LTGs, together with tectonic discrimination plots and regional data, suggest a forearc setting above the SSZ for Acite ophiolitic mélange.     

Late Cretaceous uplift history of the Cretaceous volcanic arc in Southwest Japan: Provenance analysis of the Yuasa–Aridagawa basin based on U–Pb zircon ages

The Ryoke Metamorphic complex has undergone low‐P/T metamorphism and was intruded by granitic magmas around 100 Ma. Subsequently, the belt was uplifted and exposed by the time deposition of the Izumi Group began. The tectonic history of uplift, such as the timing and processes, are poorly known despite being important for understanding the spatiotemporal evolution of the Ryoke Metamorphic Belt. U–Pb zircon ages from sedimentary rocks in the forearc and backarc basins are useful for constraining uplift and magmatism in the provenance. U–Pb dating of detrital zircons from 12 samples (four sandstones and eight granitic clasts) in the Yuasa–Aridagawa basin, a Cretaceous forearc basin in the Chichibu Belt of Southwest Japan, gave mostly ages of 60–110 Ma. Granitic clasts contained in conglomerate suggest that granitic intrusions predate the formation of Coniacian and Maastrichtian conglomerate. Emplacement ages of granitic bodies originated from granitic clasts in Coniacian conglomerate are (110.2 ±1.3) Ma, (106.1 ±1.8) Ma, (101.8+5.8–3.8) Ma, and (95.3 ±1.4) Ma; for granitic clasts in Maastrichtian conglomerate, (89.6 ±1.8) Ma, (87.3+2.4–1.8) Ma, (85.7 ±1.2) Ma, and (82.7 ±1.2) Ma. The results suggest that detrital zircons in the sandstones were mainly derived from volcanic eruptions contemporaneous with depositional age, and plutonic rocks of the Ryoke Metamorphic Belt. Zircon ages of the granitic clast samples also indicate that uplift in the provenance began after Albian and occurred at least during the Coniacian to Maastrichtian. Our results, together with the difference of provenance between backarc and forearc basins suggest that the southern marginal zone of the Ryoke Metamorphic Belt was uplifted and supplied a large amount of clastic materials to the forearc basins during the Late Cretaceous.     

弧前盆地研究进展综述

综述了弧前盆地的沉降机制,充填序列及主要识别标志,沉降机制分析表明,其沉降速率总体呈下降趋势。沉积充填序列总体表现为一向上变粗,变浅的巨层序,其具体发育规律主要受增生槛高程,充填速率与沉降速率比值控制,特殊的构造部位,弱的变形,变质和富有特色的沉积序列,砂岩碎屑组分是判别化石弧前盆地的主要标志。     

伊豆-小笠原前弧地区Hahajima海山蛇纹石化橄榄岩岩石学和地球化学研究

Serpentinites, which contain up to 13 wt% of water, are important reservoirs for chemical recycling in subduction zones. In the past two decades, forearc mantle serpentinites were identified in different locations around the world. Here, we present petrology and whole rock chemistry of ultramafic and mafic rocks dredged from the Hahajima Seamount, which is located 24–40 km west to the junction of the Izu-Bonin Trench and the Mariana Trench. Nearly all the collected samples are extensively hydrated, and olivine grains in ultramafic rocks are replaced by serpentine minerals, with only one sample preserving remaining trace of orthopyroxene. Our new results show that the Hahajima serpentinized peridotite samples are all MgO-rich(～42 wt%), but have low contents in Al_2O_3, CaO, rare earth and high field strength elements, which is consistent with the overall depleted character of their mantle protoliths. Model calculations indicate that these Hahajima peridotite samples were derived from 10%–25% partial melting of the presumed fertile mantle source, which is generally lower than those of peridotites from Torishima Forearc Seamount, Conical Seamount and South Chamorro Seamount(mostly25%). All the serpentinites from these four forearc seamounts show strong enrichment in fluid-mobile and lithophile elements(Li, Sr, Pb and U). In details, Hahajima Seamount serpentinites do not have obvious enrichment in Cs and Rb, and display remarkably high abundances of U. These observations indicate that the serpentinization of Hahajima peridotites occurred by addition of seawater or low temperature seawater-derived hydrothermal fluid, without or with little contribution from slab-derived fluids. The geochemical signature of serpentinites from Hahajima Seamount could be interpreted as the result of the combination of extensive partial melting and subsequent percolation of seawater through the mantle wedge.