南海北部深水及超深水区现今地温场及热结构特征研究

依据前人对岩石圈层结构的认识和地震反射界面揭示的沉积充填,本文对南海北部深水及超深水区域的现今地温场特征及岩石圈热结构进行了计算。结果表明：南海北部深水及超深水区具有“热盆”特征,超深水区较深水区更热,但超深水区沉积基底的现今温度较深水区低。大地热流值的总体变化趋势表现为从深水区向超深水区逐渐增高,与地壳和岩石圈向南减薄趋势一致。南海北部深水及超深水区具有“冷壳热幔”的岩石圈热结构特征。地壳热流主要由基底的构造形态和地壳减薄程度控制,地幔热流则只受控于岩石圈基底埋深。     

青藏高原东缘川滇构造区深部电性结构特征

本文对位于青藏高原东缘川滇构造区的贡山一绥江大地电磁测深(MT)剖面数据进行反演,获得沿剖面的深部电性结构,为研究喜马拉雅东构造结、川滇菱形地块与华南地块的构造变形特征、壳幔耦合关系、地块间接触关系以及相互作用等问题,提供电性结构的依据.研究发现:(1)电性结构揭示澜沧江断裂带和小金河断裂带为深大断裂带,控制着研究区的深部结构特征和形变机制;(2)澜沧江断裂带和金沙江断裂带之间的高阻体,可能是扬子古地块的残留部分;小金河断裂带和安宁河断裂带之间的高阻体,则是峨眉山大火山省喷发形成的冕宁一越西杂岩带;(3)在滇西地块、川滇地块和大凉山地块均存在低阻层,它们的介质属性有所不同,滇西地块下的低阻层"疑似"高热状态的岩浆囊,主要由缅甸弧向东俯冲运动引起的,中上地壳的高热状态使地块的活动性增强;川滇地块内部的壳内低阻层的成因为:理塘断裂带和小金河断裂带之间的地表低阻层由破碎带充水所致,而金沙江断裂带和理塘断裂带之间的中地壳低阻层可能是由局部熔融物质或含盐流体导致的,其为壳内物质运移的通道.从而在地下物质发生大规模走滑运动的过程中起到引导作用;川滇地块东部和大凉山地块西部的壳内低阻层可能与地慢物质的上涌有关;马边断裂带附近的低阻体可能与破碎带变宽和破碎带内的流体有关.     

The Avalon Zone: A Pan-African terrane in the Appalachian Orogen of Canada

The Precambrian sequences of the Avalon Zone in Canada (southeastern margin of the Appalachian Orogen) are interpreted as a Pan-African orogenic belt incorporated into the Appalachian Orogen during Palaeozoic times as its southeastern margin. The Precambrian evolution of the Avalon Zone was genetically unrelated to subsequent Palaeozoic evolution. The Avalon Zone shows marked similarities in age, tectonic history, and facies development to the Pan-African belts adjacent to the West African Craton. Precambrian evolution of the zone began with circa 800 Ma rifting of a sialic gneissic basement and deposition of a Middle Proterozoic(?) carbonate-clastic cover sequence. Early crustal rifting was associated with localized partial melting and metamorphism. Limited crustal separation led to the restricted development of circa 760 Ma oceanic volcanics. Continued rifting and subsequent closure of these narrow ocean basins led to the eruption of widespread subaerial volcanic suites, block faulting, granite plutonism, and local, late Proterozoic sedimentary basin formation. Precambrian evolution of the zone terminated with the Avalonian Orogeny (circa 650-600 Ma), a deformational event, the affects of which are most evident locally along the northwestern margin of the zone. The controlling features of the Proterozoic evolution of the Avalon Zone are a series of linear intracratonic troughs and small ocean basins that formed during thinning and separation of the crust by ductile spreading, rupture, and delamination (cf. Martin and Porada 1977). The variation in degree of crustal separation led to subsequent variation in orogenesis during late Proterozoic compression. The zone marks the original westward limit of Pan-African activity and displays no apparent genetic link with the Appalachian Orogen in Canada until Devonian times.     

全球海量地形数据组织管理方法的研究

本文通过研究全球多分辨率地形数据的特点和渲染需要,研究了现有的全球地形数据组织方法并提出改进措施。然后利用多分辨率LOD(MRLOD)技术,设计并实现了一种面向全球的分层分块方案,详细阐述了其构建规则,并分析了方案的可行性,然后详细地说明了分层分块的数据结构组织,最后利用上述提出的技术,做了一些关于某一大规模三维地形实时漫游方面的实验,文中详细列出了这些实验结果。实验结果表明,采用该文提出的方法,可以在普通PC机上实现大规模三维地形场景的实时漫游。     

A new pattern of the tectonic units and metallogenic belts in Africa continent in terms of lithosphere

Based on the comprehensive study of geology and geophysics in African continent, three types of lithosphere (craton-type, orogenic-type and rift-type) can be identified. Considering lithosphere discontinuities as the boundary, two first-order tectonic units (mainly cratonic-type in the west and rift-type in the east) are proposed. Different types of lithosphere can be divided into secondary-order and third-order structural units, and the blocks within lithosphere can be further divided into fourth-order structural units. The geological history, the formation process and significance of different types of lithosphere in African continent are briefly discussed.©2022 China Geology Editorial Office.     

豫西熊耳山蒿坪沟黑云母花岗斑岩的锆石LA-ICP-MSU-Pb年龄及其地质意义

熊耳山西端的沙沟—龙门店银多金属矿矿集区内出露蒿坪沟黑云母花岗斑岩,精确限定它的形成时代对探讨其成因背景和评价成矿潜力均具有重要意义。蒿坪沟岩体定年样品HPG304的岩性为黑云母花岗斑岩,33个锆石测点中有18个测点的U-Pb同位素测定值位于或者接近n(207Pb)/n(235U)—n(206Pb)/n(238U)一致线,它们的年龄值集中于2435±9 Ma、2310±13~2340±10 Ma、1784±10 Ma和129±1~131±1 Ma等4个年龄段内。最新年龄段内8个锆石测点n(206Pb)/n(238U)年龄加权平均值为129.9±0.6 Ma(MSWD=0.69),结合前人蒿坪沟黑云母花岗斑岩5颗SHRIMP锆石的U-Pb同位素数据,获得的加权平均年龄为130.5±1.1 Ma(MSWD=3.5),认为它的形成年龄为130.5±1.1 Ma。综合蒿坪沟黑云母花岗斑岩的SHRIMP锆石定年结果,34颗锆石形成了一个从古元古代到早白垩世的锆石年龄谱,区域上均存在与之对应的岩浆热事件。蒿坪沟黑云母花岗斑岩形成的构造背景为早白垩世岩石圈拆沉作用,由此触发的岩浆(流体)混合作用成就了其锆石U-Pb年龄谱。蒿坪沟黑云母花岗斑岩的形成时代与小秦岭—崤山—熊耳山地区中生代广泛而强烈的成矿及成岩时代相接近,岩石圈拆沉作用利于深部流体快速释放,加之蒿坪沟黑云母花岗斑岩及其周缘和深部显示了良好的物化探异常,它应当被视为沙沟—龙门店银多金属矿矿集区内找矿靶区之一。     

广义立体像对匹配方法研究

遥感影像匹配是遥感技术中的热点和难点问题,是三维重建、导航、模式识别、DEM自动提取等工作的基础.传统的匹配方法通常是针对同源数据的,文中研究基于广义立体像对的匹配方法,设计并实现了基于小波变换的特征匹配和灰度匹配相结合的匹配方法,并结合现有的遥感数据,人工选取40对同名控制点对匹配点的精度进行检验,实验结果表明该算法...     

Constraints on the paleogeographic evolution of the North China Craton during the Late Triassic–Jurassic

This paper reports U–Pb–Hf isotopes of detrital zircons from Late Triassic–Jurassic sediments in the Ordos, Ningwu, and Jiyuan basins in the western-central North China Craton (NCC), with the aim of constraining the paleogeographic evolution of the NCC during the Late Triassic–Jurassic. The early Late Triassic samples have three groups of detrital zircons (238–363 Ma, 1.5–2.1 Ga, and 2.2–2.6 Ga), while the latest Late Triassic and Jurassic samples contain four groups of detrital zircons (154–397 Ma, 414–511 Ma, 1.6–2.0 Ga, and 2.2–2.6 Ga). The Precambrian zircons in the Late Triassic–Jurassic samples were sourced from the basement rocks and pre-Late Triassic sediments in the NCC. But the initial source for the 238–363 Ma zircons in the early Late Triassic samples is the Yinshan–Yanshan Orogenic Belt (YYOB), consistent with their negative zircon ε_Hf(t) values (−24 to −2). For the latest Late Triassic and Jurassic samples, the initial source for the 414–511 Ma zircons with ε_Hf(t) values of −18 to +9 is the Northern Qinling Orogen (NQO), and that for the 154–397 Ma zircons with ε_Hf(t) values of −25 to +12 is the YYOB and the southeastern Central Asian Orogenic Belt (CAOB). In combination with previous data of late Paleozoic–Early Triassic sediments in the western-central NCC and Permian–Jurassic sediments in the eastern NCC, this study reveals two shifts in detrital source from the late Paleozoic to Jurassic. In the Late Permian–Early Triassic, the western-central NCC received detritus from the YYOB, southeastern CAOB and NQO. However, in the early Late Triassic, detritus from the CAOB and NQO were sparse in basins located in the western-central NCC, especially in the Yan’an area of the Ordos Basin. We interpret such a shift of detrital source as result of the uplift of the eastern NCC in the Late Triassic. In the latest Late Triassic–Jurassic, the southeastern CAOB and the NQO restarted to be source regions for basins in the western-central NCC, as well as for basins in the eastern NCC. The second shift in detrital source suggests elevation of the orogens surrounding the NCC and subsidence of the eastern NCC in the Jurassic, arguing against the presence of a paleo-plateau in the eastern NCC at that time. It would be subsidence rather than elevation of the eastern NCC in the Jurassic, due to roll-back of the subducted paleo-Pacific plate and consequent upwelling of asthenospheric mantle.     

Sr–Nd–Hf–Pb isotope geochemistry of basaltic rocks from the Cretaceous Gyeongsang Basin,South Korea: Implications for basin formation

To better understand the formative mechanism of the Cretaceous Gyeongsang Basin in South Korea, we determined the geochemical compositions of Early Cretaceous syntectonic basaltic rocks intercalated with basin sedimentary assemblages. Two distinct compositional groups appeared: tholeiitic to calc-alkaline basalts from the Yeongyang sub-basin and high-K to shoshonitic basaltic trachyandesites from the Jinju and Uiseong sub-basins. All collected samples exhibit patterns of light rare earth element enrichment and chondrite-normalized (La/Yb)_N ratios ranging from 2.4 to 23.6. In a primitive-mantle-normalized spidergram, the samples show distinctive negative anomalies in Nb, Ta, and Ti and a positive anomaly in Pb. The basalts exhibit no or a weak positive U anomaly in a spidergram, but the basaltic trachyandesites show a negative U anomaly. The basalts have highly radiogenic Sr [(⁸⁷Sr/⁸⁶Sr)_i = 0.70722–0.71145], slightly negative ε_Nd, positive ε_Hf [(ε_Nd)_i = −2.7 to 0.0; (ε_Hf)_i = +2.9 to +6.4], and radiogenic Pb isotopic compositions [(²⁰⁶Pb/²⁰⁴Pb)_i = 18.20–19.19; (²⁰⁷Pb/²⁰⁴Pb)_i = 15.60–15.77; (²⁰⁸Pb/²⁰⁴Pb)_i = 38.38–39.11]. The basaltic trachyandesites are characterized by radiogenic Sr [(⁸⁷Sr/⁸⁶Sr)_i = 0.70576–0.71119] and unradiogenic Nd, Hf, and Pb isotopic compositions [(ε_Nd)_i = −14.0 to −1.4; (ε_Hf)_i = −17.9 to +3.7; (²⁰⁶Pb/²⁰⁴Pb)_i = 17.83–18.25; (²⁰⁷Pb/²⁰⁴Pb)_i = 15.57–15.63; (²⁰⁸Pb/²⁰⁴Pb)_i = 38.20–38.70]. The “crust-like” signatures, such as negative Nb–Ta anomalies, elevated Sr isotopic compositions, and negative ε_Nd(t) and ε_Hf(t) values, of the basaltic trachyandesites resemble the geochemistry of Early Cretaceous mafic volcanic rocks from the southern portion of the eastern North China Craton. Considering the lower-crust-like low U/Pb and high Th/U ratios and the unradiogenic Pb isotopic compositions, the basaltic trachyandesites are considered to be derived from lithospheric mantle modified by interaction with melts that originated from foundered eclogite. Basaltic volcanism in the Yeongyang sub-basin is coeval with the basaltic trachyandesite magmatism, but it exhibits an elevated ⁸⁷Sr/⁸⁶Sr ratio at a given ¹⁴³Nd/¹⁴⁴Nd and highly radiogenic Pb isotopic compositions, which imply an origin from an enriched but heterogeneous lithospheric mantle source. Melts from subducted altered oceanic basalt and pelagic sediments are considered to be the most likely source for the metasomatism. An extensional tectonic regime induced by highly oblique subduction of the Izanagi Plate beneath the eastern Asian margin during the Early Cretaceous might have triggered the opening of the Gyeongsang Basin. Lithospheric thinning and the resultant thermal effect of asthenospheric upwelling could have caused melting of the metasomatized lithospheric mantle, producing the Early Cretaceous basaltic volcanism in the Gyeongsang Basin.