中国近海新生代盆地构造差异性演化及油气勘探方向

中国近海处于欧亚、印度-澳大利亚及太平洋三大板块的交汇地带,其盆地形成与演化受控于洋、陆板块的相互作用,区域构造背景对盆地形成和演化起到了重要的作用,并由此导致了中国近海盆地显著的分段性和差异性演化特征。渤海海域、北黄海至南黄海盆地属于陆内裂陷型盆地;东海海域为活动大陆边缘弧后裂陷型盆地;珠江口盆地和琼东南盆地为被动大陆边缘型盆地;莺歌海海域为转换大陆边缘型盆地。受此影响,油气分布有明显的分段分区性,渤海—南黄海陆内盆地以成油为主,东海弧后盆地以成气为主,南海北部大陆边缘北部成油、南部成气,莺歌海转换盆地以成气为主。中国近海未来的找油领域主要在渤海、珠江口盆地北部和北部湾盆地;找气领域主要在东海盆地、南海北部深水区和莺歌海盆地6大领域。     

鄂尔多斯盆地子洲气田北部山2段沉积体系研究

通过野外观察、岩心描述与室内研究相结合的方法,对鄂尔多斯盆地子洲气田北部山西组山2段研究,分析研究区山西组山2段的沉积相特征及沉积相带空间展布规律,确定研究区山2段主要为三角洲沉积体系。进行沉积微相的划分,掌握研究区储层砂体叠置形态规律。     

非线性弹性地基上矩形薄板的主参数共振

分析非线性弹性地基上受参数激励小挠度矩形薄板的主参数共振问题,由冯卡门方程和伽辽金方法得到系统的非线性振动方程,它是杜分-马休型方程,应用非线性振动的多尺度法得到平均方程。数值计算结果表明：阻尼系数、地基系数、几何参数对主参数共振曲线影响明显。     

上软下硬地层浅埋大跨度车站拆撑安全性分析

对于复合式衬砌隧道,初支受力最危险的时期就是为保证二次衬砌的完整性而分段拆除临时支撑的阶段。依托青岛地铁某暗挖车站,采用现场实测数据分析和数值模拟相结合的方法,对比拆撑前后围岩与初支变形情况,进而对6 m范围内交替拆撑,并以6 m为工作单元间隔拆撑的拆撑方案安全性进行分析。实测数据表明,地表沉降、拱顶沉降及净空收敛在拆撑前后增长量及影响均较小,数值计算结果与实测数据吻合较好,可知初支的安全性受支撑拆除的影响较小。研究结论为实现信息化施工提供了依据,也为今后类似工程积累了相关经验。     

青海索拉沟银多金属矿床成矿特征及成因探讨

索拉沟地区位于青海省东昆仑东部与西秦岭造山带的接合部位,地质构造复杂,岩浆活动较强烈,成矿背景条件良好,是青海省贵金属、铜多金属重要的成矿带之一。根据矿床产出的地质构造环境、成矿特征、矿物组成、电子探针、流体包裹体温压测试及元素组合等特点分析,推测矿床的形成经历了热水沉积成矿和热液叠加改造成矿,索拉沟银多金属矿为热水沉积-热液叠加改造型。     

藏北祖尔肯乌拉山地区新生代高钾钙碱岩系火山岩同位素地球化学研究

通过对藏北祖尔肯乌拉山地区新生代高钾钙碱岩系火山岩Sr,Nd,Pb同位素成分的系统测试分析表明,火山岩具有相对高的^87Sr／^86Sr和低的^143Nd／^144Nd值及高的Pb同位素组成特点,且Sr,Nd,Pb同位素比值变化范围很窄,反映了其具有同源岩浆的特点,并且经历了类似的地球化学动力学过程。Sr,Nd,Pb同位素组成及相关图解判别表明,藏北祖尔肯乌拉山地区新生代高钾钙碱岩系火山岩来源于被大洋沉积物和地壳物质所混合的不均一富集地幔源区,显示源区具有壳幔混源性质,与EMⅡ型富集地幔源特征一致。     

吉林省中部农业土壤中HCH和HCB的残留特征

通过分析测试吉林省中部农业土壤中α-HCH、β-HCH、γ-HCH、δ-HCH 4种异构体和HCB的含量,对该地区HCH和HCB的残留情况进行了讨论。结果表明,在吉林省中部农业土壤中HCH4种异构体均有不同程度的检出,其中β-HCH和γ-HCH为主要的残留物。ΣHCH残留量介于0.42~44.96 ng/g之间,平均值为5.09 ng/g;ΣHCH残留量在不同类型土壤和不同利用方式下土壤中差异不明显。农业土壤中α-HCH/γ-HCH比值均接近于1,指示该地区土壤环境已经发生变化,也可能有新的污染源存在。土壤中HCB平均值为5.51 ng/g,总体残留水平比较低,且在水田中的残留量高于在旱田中的残留量。     

Nature and Evolution of Pre-Neoproterozoic Continental Crust in South China: A Review and Tectonic Implications

South China as an amalgamation of the Yangtze and Cathaysia blocks is composed of Archean to Mesoproterozoic basement overlain by Neoproterozoic and younger cover. Both the constituent Yangtze and Cathaysia blocks contain well-preserved Neoproterozoic rocks that have been extensively studied in terms of the age and tectonic nature, but less is known about their earlier crustal history due to the incomplete rock record. Recent efforts in investigating the yet survived crustal nature based on isotopic and elemental signatures preserved in igneous and sedimentary rocks have steadily improved our knowledge about the pre-Neoproterozoic continental crustal evolution in South China. In this paper, we summarize the up-to-date pre-Neoproterozoic records, including petrological, geochronological, geochemical and geophysical data, across South China, and discuss its spatiotemporal patterns of the pre-Neoproterozoic crust and the relevant tectonic events. While the xenocrystic/inherited and detrital zircon records suggest widespread Archean (mainly ca. 2.5 Ga) crustal components within both the Yangtze and Cathaysia blocks, exposed Archean rocks are only limited to isolated crustal provinces in the Yangtze Block. These Archean rocks are dominated by TTGs (tonalite-trondhjemite-granodiorite) with varied ages (3.3–2.5 Ga) and zircon Hf isotopes, indicating a compositionally heterogeneous nature of the Archean Yangtze Block and, by inference, the development of multiple ancient terranes. The early Paleoproterozoic (2.4–2.2 Ga) tectonomagmatic events characterize the western Yangtze Block and are supportive of an east-west subdivision of the Yangtze basement, whereas the late Paleoproterozoic (2.1–1.7 Ga) orogeneses may have affected a larger area covering both the western and eastern parts of the Yangtze Block, and also the Cathaysia Block. The eastern Yangtze Block with generally northeastward-younging late Paleoproterozoic magmatism and metamorphism likely experienced a prolonged 2.05–1.75 Ga orogenic process welding the various Archean proto-continents, consistent with the documentation of a buried late Paleoproterozoic orogenic belt imaged by deep seismic profiling from its central part and of a slightly older ophiolitic mélange in the northern part. The Cathaysia Block was probably involved in a short-lived 1.9–1.8 Ga orogenic event. The two orogeneses overlapped in time and may have contributed to the cratonization of a possible unified South China, and are referred to be linked with the assembly of the Nuna Supercontinent. The subsequent late Paleoproterozoic to early Mesoproterozoic rift successions and intrusions (1.7–1.5 Ga) in the southwestern Yangtze Block, and the ca. 1.43 Ga rifting in Hainan Island of the Cathaysia Block could be responses to the Nuna break-up. Late Mesoproterozoic (1.2–1.0 Ga) magmatism of varied age and nature in different localities of the Yangtze Block is reflective of a complex tectonic process in the context of the assembly of the Rodinia Supercontinent. Similar-aged metamorphism (1.3–1.0 Ga) is recorded in Hainan Island, reflecting the Grenvillian continental collision during the Rodinia assembly, but further studies are necessary to better constrain the late Mesoproterozoic tectonic framework of South China.